Evaluation of Effective Microorganisms (EM®) against Root-Knot Nematode (Meloidogyne javanica) in Tomato

H. Charehgani, Saeidi Mahdi
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Latest interest in organic farming lead to substitution for conventional nematicides by low-risk compounds such as natural products derived from plants (Oka et al. 2006). Also, biological control is an interesting option to control these nematodes (Mosahaneh et al. 2020). Effective microorganisms (EM®) consist of a mixture of live cultures of microorganisms such as photosynthetic bacteria, which they are reported to reduce the incidence of pathogenic microorganisms (Condor et al., 2007). Materials and Methods: In the present study, the aerial parts of the marigold (Tagetes erecta) were collected from Shiraz, Iran. Marigold leaves dried in shade and finely grinded using an electric grinder and a stock solution (10% w/v) was prepared. Seeds of tomato (cv. Early-Urbana) were sown in plastic pots containing 1500 g of a sterilized mixture of farm soil (sandy loam soil) and cow manure. The pots were kept under greenhouse conditions with 16:8 h light to dark photoperiod and 27 ± 4 °C. Four-leaf stage seedlings were soil-drenched (50 ml per plant) with EM® or a mixture of equal amount of EM®+ marigold leaf extract at the rate of 5, 10, 15 and 20% and simultaneously inoculated with a suspension of M. javanica (6000 eggs per pot). The experiment was carried out in a completely randomized design with five replications. Sixty days after nematode inoculation, plants were harvested and the vegetative indices including shoots length, shoot fresh and dry weight and root fresh weight and the nematode population indices including the number of eggs as described by Hussey and Barker (1973), number of galls and egg masses per root system as described by Taylor and Sasser (1978) and the number of second stage juveniles (J2s) in the pot were recorded. Finally, the reproduction factor calculated as described by Sasser and Taylor (1978). 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The number of eggs and egg masses per root system and the reproduction factor were significantly reduced in treated plants with EM®+ marigold leaf extract at the rate of 15 and 20%. EM®+ marigold leaf extract at the rate of 20% reduced the number of eggs, galls, egg masses per root system and the reproduction factor by 28, 40, 37 and 27% respectively, as compared to control. The lowest numbers of eggmasses were observed in the root system of tomato plants treated with EM®+ marigold leaf extract at the rate of 20%. It had significant difference than other treatments, except EM® at the rate of 20%. These data for the first time in Iran, suggest that EM® might have utility in controlling root-knot nematodes. A mixture of EM® and marigold leaf extract was more effective than alone application of EM® for control of M. javanica. Findings from this study, suggest that a mixture of equal amount of EM® and marigold leaf extract at the rate of 20% reduced M. javanica reproduction rates in tomato plants grown in greenhouse.","PeriodicalId":16965,"journal":{"name":"Journal of Plant Protection","volume":"30 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2021-06-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Plant Protection","FirstCategoryId":"1091","ListUrlMain":"https://doi.org/10.22067/JPP.2021.67213.0","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
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Abstract

Introduction: Plant-parasitic nematodes cause significant yield losses in a wide range of crops (Nicol et al. 2011). Root-knot nematodes (Meloidogyne spp.) are the most important plant-parasitic nematodes, because they widely distributed all around the world and have wide host range (Chapuis-Lardy et al. 2015). Chemical nematicide is one of the primary means of control for plant-parasitic nematodes. Due to negative impact of synthetic nematicides, it will be necessary to develop other management strategies for plant-parasitic nematodes which are safe for the environment and humans (Huang et al., 2016). Latest interest in organic farming lead to substitution for conventional nematicides by low-risk compounds such as natural products derived from plants (Oka et al. 2006). Also, biological control is an interesting option to control these nematodes (Mosahaneh et al. 2020). Effective microorganisms (EM®) consist of a mixture of live cultures of microorganisms such as photosynthetic bacteria, which they are reported to reduce the incidence of pathogenic microorganisms (Condor et al., 2007). Materials and Methods: In the present study, the aerial parts of the marigold (Tagetes erecta) were collected from Shiraz, Iran. Marigold leaves dried in shade and finely grinded using an electric grinder and a stock solution (10% w/v) was prepared. Seeds of tomato (cv. Early-Urbana) were sown in plastic pots containing 1500 g of a sterilized mixture of farm soil (sandy loam soil) and cow manure. The pots were kept under greenhouse conditions with 16:8 h light to dark photoperiod and 27 ± 4 °C. Four-leaf stage seedlings were soil-drenched (50 ml per plant) with EM® or a mixture of equal amount of EM®+ marigold leaf extract at the rate of 5, 10, 15 and 20% and simultaneously inoculated with a suspension of M. javanica (6000 eggs per pot). The experiment was carried out in a completely randomized design with five replications. Sixty days after nematode inoculation, plants were harvested and the vegetative indices including shoots length, shoot fresh and dry weight and root fresh weight and the nematode population indices including the number of eggs as described by Hussey and Barker (1973), number of galls and egg masses per root system as described by Taylor and Sasser (1978) and the number of second stage juveniles (J2s) in the pot were recorded. Finally, the reproduction factor calculated as described by Sasser and Taylor (1978). Data were subjected to one-way analysis of variance (ANOVA) for plant growth parameters and two-way ANOVA for nematode population indices using SAS 9.1 program (Statistical Analysis System Institute Inc., USA). Treatment means were compared using least significance differences (LSD) at p<0.01.Results and Discussion: Results showed that soil drenching of EM® and EM®+ marigold leaf extract increased the plant growth parameters on inoculated and non-inoculated plants as compared to control. The treatment with EM®+ marigold leaf extract at the rate of 20% was the most effective treatment and increased shoot length, shoot fresh weight and shoot dry weight of non-inoculated plants by 33, 39 and 11% respectively, as compared to non-inoculted control plants. In the case of inoculated plants, shoot length, shoot fresh weight, shoot dry weight and root fresh weight of treated plats with EM®+ marigold leaf extract at the rate of 20% were 34, 31, 15 and 11% higher than inoculated control plants. The number of eggs and egg masses per root system and the reproduction factor were significantly reduced in treated plants with EM®+ marigold leaf extract at the rate of 15 and 20%. EM®+ marigold leaf extract at the rate of 20% reduced the number of eggs, galls, egg masses per root system and the reproduction factor by 28, 40, 37 and 27% respectively, as compared to control. The lowest numbers of eggmasses were observed in the root system of tomato plants treated with EM®+ marigold leaf extract at the rate of 20%. It had significant difference than other treatments, except EM® at the rate of 20%. These data for the first time in Iran, suggest that EM® might have utility in controlling root-knot nematodes. A mixture of EM® and marigold leaf extract was more effective than alone application of EM® for control of M. javanica. Findings from this study, suggest that a mixture of equal amount of EM® and marigold leaf extract at the rate of 20% reduced M. javanica reproduction rates in tomato plants grown in greenhouse.
番茄根结线虫(Meloidogyne javanica)有效微生物(EM®)的评价
植物寄生线虫对多种作物造成重大产量损失(Nicol et al. 2011)。根结线虫(Meloidogyne spp.)是最重要的植物寄生线虫,因为它们在世界各地分布广泛,宿主范围广(Chapuis-Lardy et al. 2015)。化学杀线虫剂是防治植物寄生线虫的主要手段之一。由于合成杀线虫剂的负面影响,有必要制定对环境和人类安全的植物寄生线虫的其他管理策略(Huang et al., 2016)。最近对有机农业的兴趣导致用低风险化合物(如从植物中提取的天然产品)替代传统的杀线虫剂(Oka等,2006年)。此外,生物防治是控制这些线虫的一个有趣的选择(Mosahaneh et al. 2020)。有效微生物(EM®)由光合细菌等微生物的活培养物的混合物组成,据报道,它们可以减少病原微生物的发病率(Condor et al., 2007)。材料与方法:本研究采自伊朗设拉子地区万寿菊(Tagetes erecta)的地上部分。将万寿菊叶片在阴凉处晒干,用电磨机磨细,配制成原液(10% w/v)。番茄种子(cv。早期乌尔班纳(early urbana)种植在塑料罐中,罐中装有1500克农场土壤(沙质壤土)和牛粪的消毒混合物。盆栽置于温室条件下,明暗光照周期为16:8 h,温度为27±4℃。四叶期幼苗用EM®或等量EM®+万金菊叶提取物的混合物以5%、10%、15%和20%的比例浸土(每株50 ml),同时接种javanica菌悬液(每罐6000个卵)。试验采用完全随机设计,共5个重复。接种线虫60 d后,采收植株,记录幼苗的营养指标(芽长、茎鲜、干重、根鲜重)和线虫种群指标(Hussey and Barker(1973)描述的卵数、Taylor and Sasser(1978)描述的每个根系的虫瘿数和卵块数以及盆栽中第二阶段幼虫数)。最后,根据Sasser和Taylor(1978)的描述计算繁殖因子。采用SAS 9.1软件(Statistical analysis System Institute Inc., USA)对植物生长参数进行单因素方差分析,对线虫种群指数进行双因素方差分析。采用最小显著性差异(LSD)比较,p<0.01。结果与讨论:结果表明,与对照相比,EM®和EM®+万金菊叶提取物对接种和未接种植株的生长参数均有提高。EM®+金盏花叶提取物浓度为20%的处理效果最好,与未接种植株相比,未接种植株的茎长、茎鲜重和茎干重分别增加了33%、39%和11%。在接种植株的情况下,EM®+金盏花叶提取物浓度为20%的处理植株的茎长、茎鲜重、茎干重和根鲜重分别比接种对照植株高34、31、15%和11%。EM®+金盏花叶提取物在15%和20%的浓度下显著降低了植株根系的卵数、卵质量和繁殖因子。EM®+金盏花叶提取物浓度为20%时,与对照相比,每个根系的卵数、虫瘿数、卵质量和繁殖系数分别降低了28%、40%、37%和27%。EM®+万寿菊叶提取物浓度为20%时,番茄根系中卵细胞数量最少。它与其他治疗有显著差异,除EM®为20%。这些数据首次在伊朗得到,表明EM®可能在控制根结线虫方面具有实用价值。EM®与万金菊叶提取物混合施用对爪哇菊的防治效果优于单独施用EM®。本研究结果表明,等量EM®和金盏花叶提取物以20%的比例混合,可降低温室栽培番茄植株上javanica的繁殖率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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