Cover crops and biocontrol agents in the management of nematodes in soybean crop

Araujo, Fernando G. de; Teixeira, Samuel J. C.; de Souza, Jean C.; Arieira, Claudia R. D.

doi:10.1590/1983-21252023v36n201rc

ABSTRACT

In the Brazilian Cerrado, phytonematodes, phytonematodes are a challenge for agriculture, and the association of forms of control is the best strategy to be used in coexistence with this pathogen. Faced with this problem, this study aimed to evaluate the efficiency of cover crops and biocontrol agents in the management of nematodes in soybean. For each nematode species under study (Meloidogyne incognita and Pratylenchus brachyurus), two experiments were carried out under greenhouse conditions in a completely randomized design arranged in a 6 × 2 factorial scheme with eight replications. Six cover crops (millet ADRG 9050, millet ADR 300, Urochloa ruziziensis, Crotalaria ochroleuca, C. spectabilis, and corn hybrid DKB 290) and two treatments (treated or not with Bacillus subtilis and B. methylotrophicus - 1×10⁶ CFU per seed) were evaluated. The cover crops were sown in soil infested with nematodes and then soybeans were sown under the straw, and cultivated for 45 and 60 days, for M. incognita and P. brachyurus, respectively. Fresh root mass, total nematode population, and the number of nematodes per gram of root were evaluated. The association of microorganisms with C. spectabilis, U. ruziziensis, and millet ADR 300 conferred an additional effect in reducing the population of P. brachyurus. For M. incognita, the association was successful only for combining C. spectabilis with B. methylotrophicus. DKB 290 corn, when treated with B. methylotrophicus, had the nematode population per gram of soybean root reduced by 90% compared to plants that did not receive biological treatment.

Keywords:
Meloidogyne incognita ; Pratylenchus brachyurus ; Biological control

RESUMO

No Cerrado brasileiro, os fitonematoides são um desafio para agricultura, sendo a associação de formas de controle a melhor estratégia a ser utilizada na convivência com esse patógeno. Diante dessa problemática, o objetivo desse trabalho foi avaliar a eficiência de plantas de cobertura e agentes de biocontrole no manejo de nematoides na cultura da soja. Foram desenvolvidos dois ensaios em condições de casa de vegetação para os nematoides Meloidogyne incognita e Pratylenchus brachyurus, em delineamento inteiramente casualizado, em esquema fatorial 6 (plantas de cobertura: milheto ADRG 9050, milheto ADR 300, Urochloa ruziziensis, Crotalaria ochroleuca, C. spectabilis e milho DKB 290) × 2 (tratados ou não com Bacillus subtilis e B. methylotrophicus - 1×10⁶ UFC por semente), com oito repetições. As plantas de cobertura foram semeadas em solo infestado com nematoides e na sequência semeada soja sob a palha, e cultivada por 45 e 60 dias, para M. incognita e P. brachyurus, respectivamente. Foram avaliadas a massa fresca de raízes e o número de nematoides totais e por grama de raiz. A associação dos microrganismos com C. spectabilis, U. ruziziensis e milheto ADR 300 conferiram efeito adicional na redução da população de P. brachyurus. Para a espécie M. incognita a associação foi bem sucedida apenas para a combinação da C. spectabilis com B. methylotrophicus. O milho DKB 290, quando tratado com B. methylotrophicus, teve a população do nematoide por grama de raiz da soja reduzida em 90 % em comparação às plantas que não receberam o tratamento biológico.

Palavras-chave:
Meloidogyne incognita ; Pratylenchus brachyurus ; Controle biológico

INTRODUCTION

In the Brazilian Cerrado, several genera of nematodes are associated with cropping systems, especially the soybean cyst nematode - SCN (Heterodera glycines), root-lesion nematodes (Pratylenchus brachyurus and P. zeae), root-knot nematodes (Meloidogyne incognita and M. javanica), reniform nematode (Rotylenchulus reniformis) and spiral nematode (Helicotylenchus dihystera and Scutellonema brachyurus) (DIAS et al., 2010DIAS, W. P. et al. Nematoides em Soja: Identificação e Controle. Londrina, PR: Embrapa Soja, 2010. 8 p. (Circular Técnica 76).). Among these genera, the root lesion nematode has great expression due to its wide distribution and a high degree of polyphagy.

P. brachyurus is a migratory endoparasite that moves inside the roots, causing mechanical damage and releasing toxins and enzymes in the root cortex, both during penetration and movement, causing the destruction of the root system and, as a result, they are known as root lesion nematode. They rank second in terms of global and national economic damage and impacts. Losses can reach up to 50% in soybean yield (GOULART, 2008GOULART, A. M. C. Aspectos Gerais Sobre Nematoides-das-lesões-radiculares (Gênero Pratylenchus). 1 ed., Planaltina, DF: Embrapa Cerrados, 2008. 27 p.). However, in soybean, losses have increased dramatically in recent seasons, reaching 50% in Cerrado soils (FRANCHINI et al., 2014FRANCHINI, J. C. et al. Perda de produtividade da soja em área infestada por nematoide das lesões radiculares na região médio norte do Mato Grosso. In: BERNARDI, A. C. C. et al. (Eds.). Agricultura de precisão: resultados de um novo olhar. Brasília, DF: Embrapa, 2014. v. 1. , cap. 24, p. 274-278.). This is because the nematode has been benefiting from changes in the production system and the incorporation of areas with sandy textured soils, further increasing the vulnerability of the crop.

Controlling nematodes is a difficult task. Generally, the producer needs to live with the pathogen through the management of population levels in the soil. Control methods against nematodes have relative efficiency because they have a low permeable cuticle, which gives them great resistance to physical and chemical agents (AlCANFOR et al., 2001ALCANFOR, D. C. et al. Controle de nematóides de galhas com produtos naturais. Horticultura Brasileira, 19: Suplemento - CD ROM, 2001.). Succession with resistant crops is the primary tool for suppressing this bridge of survival between crops. Without a susceptible host, the pathogen dies without food or completing its life cycle, thus acting as a control by relative eradication of the initial inoculum, preventing damage to the main crop (JOHNSON, 1985JOHNSON, A. W. Specific crop rotation practices combined with cultural practices and nematcides. An Advanced Treatise on Meloidogyne. v. 1. Biology and control, 1: 283–301, 1985.).

Biological control has shown promising results in keeping populations low and reducing the economic damage caused by the pathogen. Among the potential agents for biological control, bacteria of the genus Bacillus stand out. Although they do not directly parasitize nematodes, species of the Bacillus genus have multiple forms of action on these pathogens. Bacillus spp. can act on nematodes by antibiosis; that is, the bacterium produces substances that inhibit the hatching of eggs and the migration of nematodes in the soil for food. Another mode of action is competition, in which the bacterium colonizes the root and forms a physical and chemical barrier, preventing or hindering the nematode from entering the root system. In addition, when they are associated with the roots or in their surroundings (rhizosphere), Bacillus release chemicals that mimic this region and make it difficult for the nematode to locate the root system (ARIEIRA, 2020ARIEIRA, C. R. D. Bacillus: importante aliado no controle biológico de nematoides. 2020. Disponível em: https://ilustrado.com.br/bacillus-importante-aliado-no-controle-biologico-de-nematoides. Acesso em: 20 out. 2022.
https://ilustrado.com.br/bacillus-import... ).

The association of Bacillus species has shown promising effects when used together with cover crops, especially those that do not resist all nematode species (SILVA, 2016SILVA, R. A. Manejo integrado de fitonematoides em soja e algodão. Revista Cultivar: Programas de aplicações, 201: 45-50, 2016.). Costa, Pasqualli and Prevedello (2014)COSTA, M. J. N.; PASQUALLI, R. M.; PREVEDELLO, R. Effect of soil organic matter content, cover crop and planting system on the control of Pratylenchus brachyurus in soybean. Summa phytopathol, 40: 63-70, 2014. found that C. spectabilis, even not treated with biocontrol agents, contributes significantly to reducing the P. brachyurus population. In addition to this contribution, the results show that C. spectabilis, when treated with B. subtilis, reduced the total nematode population and the population per gram of root by 88% and 80%, respectively. In this context, the present study aimed to evaluate the efficiency of cover crops and the species of Bacillus subtilis and B. methylotrophicus in the management of the nematodes P. brachyurus and M. incognita in the soybean crop.

MATERIAL AND METHODS

In a completely randomized design, four experiments were carried out under greenhouse conditions at the State University of Maringá, two with P. brachyurus and two with M. incognita. The experiments with P. brachyurus were arranged in a 6 × 2 factorial scheme (six cover crops, with and without the application of biological), with ten replications, and the experiments with M. incognita in a 5 × 2 factorial scheme (cover crops, with and without the application of biological), with eight replications (Table 1). In the first experiment, for both nematodes, biological treatment was used with B. methylotrophicus UFPEDA 20 and, in the second, B. subtilis UFPEDA 764 as a biocontrol agent (Table 1).

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Table 1
Description of treatments with the cover crops treated and not treated with the microorganisms Bacillus methylotrophicus (Experiments 1 and 3) and B. subtilis (Experiments 2 and 4), and their concentrations per seed, in the studies with Pratylenchus brachyurus and Meloidogyne incognita.

Initially, soybean seeds of the cultivar BRASMAX DESAFIO RR were deposited in pots with 2 L of soil and sand (proportion 1:1) autoclaved for 2 hours at 120 °C. Ten days after sowing, the plants were inoculated with 500 specimens of P. brachyurus or 4,000 eggs and eventual second-stage juveniles (J2) of M. incognita. Inoculums were obtained from pure populations of nematodes, kept in soybean, in a greenhouse for two months, and extracted from the roots by the extraction process proposed by Hussey and Barker (1973)HUSSEY, R. S.; BARKER, K. R. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Disease Reporter, 57: 1025-1028, 1973. and adapted by Boneti and Ferraz (1981)BONETI, J. I. S.; FERRAZ, S. Modificação do método de Hussey e Barker para extração de ovos de Meloidogyne exigua de raízes de cafeeiro. Fitopatologia Brasileira, 6: 553-553, 1981.. This study step aimed to enable the prior multiplication of the nematode in the same container where the cover crops were sown, simulating a soil with cultural remains of soybean roots parasitized by the nematode.

After 45 days of inoculation for the experiments with P. brachyurus and 50 days for the experiments with M. incognita, the shoot of the soybean plants was discarded, the soil was lightly turned, and then, the treatments were introduced, which consisted of the plants: Crotalaria ochroleuca, C. spectabilis, Urochloa ruziziensis (=Brachiaria ruziziensis), millet cv. ADRG 9050, millet ADR 300, and corn DKB 290, with or without seed treatment, with the products B. methylotrophicus in the first and B. subtilis in the second. For the experiments with M. incognita, C. ochroleuca was not used. For C. ochroleuca and B. ruziziensis, two seeds were deposited per pot, while for the other species, only one seed per pot. For seed treatment, an amount of 1×10⁶ propagules of Bacillus sp. per seed was used. The product volume was deposited on the seeds, regardless of the number of seeds per pot, being the concentrations of the commercial products B. methylotrophicus (1×10⁹) and B. subtilis (3×10⁹).

The cover crops were cultivated for 70 days, and the shoot was cut and placed on the ground. Subsequently, each pot received a soybean seed, cultivated for 70 days for the experiments with P. brachyurus and 60 days with M. incognita. Then, the plants were collected, separating shoots and roots. The roots were carefully washed, weighed, and subjected to nematode extraction according to the methodology proposed by Coolen and D'Herde (1972)COOLEN, W. A.; D’HERDE, C. J. A method for the quantitative extraction of nematodes from plant tissue. Ghent: State Nematology and Entomology Reserch Station, 1972, 77 p.. In a Peter Chamber, under an optical microscope, the total population of nematodes was determined, and the number of nematodes per gram of root was calculated.

The nematological data were submitted to the analysis of Generalized Linear Models (GLM), following the Poisson distribution and the means compared by the Tukey test for GLM at 5% probability. Generalized Linear Models (GLM) were used for the biometric data, following the Gamma distribution and the means compared by the Tukey test for GLM at 5% probability.

RESULTS AND DISCUSSION

There was a significant interaction of the treatment of cover crops seeds with the product B. methylotrophicus for the number of specimens of P. brachyurus per gram of root and the total number of specimens. All treatments with cover crops treated with Bacillus methylotrophicus promoted a reduction in the total number of nematodes in soybean cultivated in sequence, compared to corn, with the treatments being more efficient in controlling the nematode: C. ochroleuca, followed by millet ADR 300, C. spectabilis, U. ruziziensis, and millet ADRG 9050 (Table 2).

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Table 2
Pratylenchus brachyurus total and per gram of soybean root after cultivation of cover crops, whose seeds were treated or not with Bacillus methylotrophicus and percentage of nematode reduction within each cover crop, at 70 days after sowing.

Although the multiplication of P. brachyurus under the effect of U. ruziziensis has already been elucidated by Silva et al. (2013)SILVA, R. A. et al. Reação de cultivares de Brachiaria spp. a Pratylenchus brachyurus. Revista Connection Line, 9: 122–129, 2013., in this study, we observed that when we treated U. ruziziensis seeds with B. methylotrophicus, there was a reduction of 53% and 67% in the total nematode population and per gram of root, respectively.

In the treatment without B. methylotrophicus, the greatest reductions of P. brachyurus were promoted by the treatments C. spectabilis, C. ochroleuca, millet ADR300, and U. ruziziensis. Results corroborate with Cruz, Asmus and Garcia (2020)CRUZ, T. T.; ASMUS, G. L.; GARCIA, R. A. Espécies de Crotalaria em sucessão à soja para o manejo de Pratylenchus brachyurus. Ciencia Rural, 50: 1-8, 2020., where reductions in P. brachyurus populations are evidenced only by the effect of using sunn hemp in succession.

The nematode population per gram of root in soybean cultivated after ADRG9050 millet was higher than that observed in corn without biological application (Table 2). These data indicate that, except millet ADRG9050, the cover crops themselves efficiently reduce the population of P. brachyurus. However, when the effect of the B. methylotrophicus treatment was studied within each cover, it was possible to observe the additional gain of the integrated management associating cover crops with biological control. The exceptions were C. spectabilis and corn, for which the association with B. methylotrophicus had no positive effect on reducing total nematode populations.

The results of the present study corroborate with Silva et al. (2018)SILVA, R. A. et al. Efeito da Rotação de culturas no manejo de nematoides em áreas arenosa. Nematropica, 48: 198-206, 2018.. The authors observed that soybean rotation with C. ochroleuca led to a reduction in P. brachyurus population density. In this context, it is observed that C. ochroleuca can reduce the population of P. brachyurus, but the association with B. methylotrophicus increases the effect of the legume in reducing the population of the nematode.

Analyzing the number of nematodes per gram of root, the results were significant since, except for corn, for which the association with B. methylotrophicus did not differ from untreated plants, the other treatments were efficient in controlling the nematode (Table 2). For this variable, the reductions promoted by B. methylotrophicus were 67% when associated with millet ADR300 and U. ruziziensis and 55% when the bacterium was applied with C. ochroleuca. The use of B. methylotrophicus with millet ADRG9050 and C. spectabilis reduced the nematode population by 27% and 16%, respectively.

The fresh mass of roots of soybean plants only differed according to the different cover crops used, regardless of the biological treatment. The highest fresh root masses were observed in soybeans cultivated in succession to corn and the two Crotalaria species (Table 3). In addition to these species, corn also promoted an increase in the root mass of the subsequent soybean.

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Table 3
Fresh mass of shoot and root of soybean infected by Pratylenchus brachyurus after cultivation of cover crops, whose seeds were treated or not treated with Bacillus methylotrophicus regardless of the treatment.

From the results obtained in the experiments with M. incognita, it was verified that in susceptible plants, such as corn, the treatment with B. methylotrophicus was quite efficient, reducing the multiplication of the root-knot nematode by 91.3% (Table 4). In addition to the treatment with corn, the treatment with B. methylotrophicus also promoted an additive effect (33.9%) in reducing nematodes in soybean cultivated after C. spectabilis.

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Table 4
Meloidogyne incognita total and per gram of soybean root after cultivation of cover crops, whose seeds were treated or not with Bacillus methylotrophicus and percentage of nematode reduction within each cover crop, at 60 days after sowing.

In general, soybean cultivated after cover crops treated with B. methylotrophicus had the highest number of total nematodes (Table 4). On the other hand, evaluating the number of nematodes per gram of root, it was observed that B. methylotrophicus promoted reductions in a population density ranging from 7.0% (for soybean cultivated after millet ADR9050) to 93.2% (for soybean grown after corn). Such reductions were 24.7 and 79.2% for soybean cultivation after U. ruziziensis and C. spectabilis when treated with B. methylotrophicus. The gain in root volume explains that the action of B. methylotrophicus can be better visualized in the analysis of nematodes per gram of root since many rhizobacteria are considered plant growth promoters.

The cover crops individually controlled the nematode, with reductions in total nematode numbers that ranged from 49.5% to 94.6% and in the numbers of nematodes per gram of root, whose reductions ranged from 70.1% to 91 .0%. Likewise, B. methylotrophicus applied to the susceptible plant (corn DKB 290) also efficiently controlled M. incognita. The interaction between cover crops and biological control agents is complex and needs better elucidation.

In plants treated with B. subtilis, it was observed that except for U. ruziziensis, whose final nematode population in soybean was higher than that found in corn, there was a reduction in the reproduction of P. brachyurus for the succession with the other coverings, C. spectabilis being the most efficient in reducing the nematode, followed by C. ochroleuca, millet ADR 300 and millet ADRG 9050 (Table 5). Crotalaria species contribute to reducing soil nematodes through different mechanisms, such as non-host or alternative host behavior; production of toxic or inhibitory allelochemicals; stimulation of antagonistic flora and fauna; entrapment of the nematode in the root, inhibiting its multiplication (WANG; SIPES; SCHMITT, 2002WANG, K. H.; SIPES, B. S.; SCHMITT, D. P. Crotalaria as a cover crop for nematode management: a review. Department of Plant and Environmental Protection Sciences University of Hawaii, Honolulu, U.S.A. Nematropica, 32: 35-57, 2002.).

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Table 5
Pratylenchus brachyurus total in soybean root after cultivation of cover crops, whose seeds were treated or not treated with Bacillus subitilis and percentage of nematode reduction within each cover crop, at 70 days after sowing.

There was a significant interaction between the treatment of cover crops seeds with B. subtilis for the total number of nematodes. All cover crops that did not receive B. subtilis efficiently reduced the nematode in soybeans planted in succession (Table 5). Still, for the total number of nematodes, evaluating the effect of B. subtilis within each plant, it was found high efficiency of the bacterium in promoting nematode control, with the greatest reductions observed for the association with C. spectabilis and corn DKB 290, with 88% and 78%, respectively, followed by C. ochroleuca and millet ADR300, with 62%, U. ruziziensis, 57%, and finally millet ADRG9050, with 23% reduction in the reproduction of P. brachyurus. Similar results were observed for the number of nematodes per gram of root, whose reproduction reductions in the soybean crop ranged from 17% for millet ADRG9050 to 80% for corn and C. spectabilis (Table 5).

These results corroborate the information that Oliveira et al. (2019)OLIVEIRA, K. C. L. et al. Biological management of Pratylenchus brachyurus in soybean crops. Revista Caatinga, 32: 41-51, 2019. found on the effect of B. subtilis on P. brachyurus. In the study, the authors obtained an almost 88% reduction in nematode reproduction factor 60 days after sowing soybean seeds treated with B. subtilis.

Costa, Pasqualli and Prevedello (2014)COSTA, M. J. N.; PASQUALLI, R. M.; PREVEDELLO, R. Effect of soil organic matter content, cover crop and planting system on the control of Pratylenchus brachyurus in soybean. Summa phytopathol, 40: 63-70, 2014. found that the C. spectabilis, even not treated with biocontrol agents, contributes significantly to reducing the P. brachyurus population. In addition to this contribution, the results show that C. spectabilis, when treated with B. subtilis, reduced the total nematode population and the population per gram of root by 88% and 80%, respectively.

Other results, such as those of Silva (2016)SILVA, R. A. Manejo integrado de fitonematoides em soja e algodão. Revista Cultivar: Programas de aplicações, 201: 45-50, 2016., showed that Bacillus species had good effects when used together with cover crops, especially those that do not show resistance to all nematode species. An excellent example is the brachiaria, which efficiently manages root-knot and cyst nematodes but hosts P. brachyurus. In this case, the use of U. ruziziensis has been recommended because, among the brachiaria species, this is one of the least favorable to the multiplication of this nematode.

There was no statistical difference for the root fresh mass of plants treated with B. subtilis. At the same time, for the untreated, higher averages were observed for treatments with both Crotalaria species (Table 6).

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Table 6
Root fresh mass of soybean parasitized by Pratylenchus brachyurus, cultivated after cover crops, with or without treatment with Bacillus subtilis.

In the experiment with B. subtilis and M. incognita, it was possible to notice that in the presence of the bacterium, all the cover crops reduced the multiplication of the nematode, with control for the total number of nematodes varying from 24.5% to 96.3% and the number of nematodes per gram of root ranging from 24.9% to 96.3% (Table 7). On the other hand, in the absence of treatment with B. subtilis, there was an increase in the multiplication of the nematode in soybean cultivated after cover crops concerning corn.

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Table 7
Meloidogyne incognita total and per gram of soybean root after cultivation of cover crops, whose seeds were treated or not treated with Bacillus subitilis and percentage of nematode reduction within each cover crop, at 60 days after sowing.

Interestingly, for soybean grown after corn treated with B. subtilis, nematode reproduction was very pronounced (Table 7), and here, it is hypothesized that the association with the bacterium may have altered corn susceptibility to the nematode. Once again, the possibility of an endophytic activity of this bacterium with the studied plants must be addressed. Despite limited research, it is known that endophytic organisms establish a very restricted interaction with their host. To colonize the cortex cells, they need to silence the defense genes of plants temporarily. During this period, the plant may be fully exposed to the attack of pathogens, and here, as the initial inoculum was high (4000 eggs + J2), there may have been a massive infection of the roots. Although the information on the treatment of cover crops seeds was not elucidated, Basyony and Abo-Zaid (2018)BASYONY, A. G.; ABO-ZAID, G. A. Biocontrol of the rootknot nematode, Meloidogyne incognita, using an eco-friendly formulation from Bacillus subtilis, lab. and greenhouse studies. Egyptian Journal Biological Pest Control, 28: 1-13, 2018. observed that the application of B. subtilis could reduce the number of galls and the egg mass of M. incognita.

CONCLUSION

The association of B. subitilis and B. methylotrophicus with C. spectabilis, U. ruziziensis, and Millet ADR 300 confers an additional effect on P. brachyurus control. A pronounced effect on this reduction is observed in the association of B. subtilis with the grasses used in this study.

For the nematode M. incognita, the association was successful only for combining C. spectabilis with B. methylotrophicus. Although DKB 290 corn is not a cover crop, it is noted that when previously treated with B. methylotrophicus, the nematode population per gram of root is reduced by 90% in soybeans grown in succession.

REFERENCES

ALCANFOR, D. C. et al. Controle de nematóides de galhas com produtos naturais. Horticultura Brasileira, 19: Suplemento - CD ROM, 2001.
ARIEIRA, C. R. D. Bacillus: importante aliado no controle biológico de nematoides 2020. Disponível em: https://ilustrado.com.br/bacillus-importante-aliado-no-controle-biologico-de-nematoides. Acesso em: 20 out. 2022.
» https://ilustrado.com.br/bacillus-importante-aliado-no-controle-biologico-de-nematoides.
BASYONY, A. G.; ABO-ZAID, G. A. Biocontrol of the rootknot nematode, Meloidogyne incognita, using an eco-friendly formulation from Bacillus subtilis, lab. and greenhouse studies. Egyptian Journal Biological Pest Control, 28: 1-13, 2018.
BONETI, J. I. S.; FERRAZ, S. Modificação do método de Hussey e Barker para extração de ovos de Meloidogyne exigua de raízes de cafeeiro. Fitopatologia Brasileira, 6: 553-553, 1981.
CRUZ, T. T.; ASMUS, G. L.; GARCIA, R. A. Espécies de Crotalaria em sucessão à soja para o manejo de Pratylenchus brachyurus Ciencia Rural, 50: 1-8, 2020.
COOLEN, W. A.; D’HERDE, C. J. A method for the quantitative extraction of nematodes from plant tissue Ghent: State Nematology and Entomology Reserch Station, 1972, 77 p.
COSTA, M. J. N.; PASQUALLI, R. M.; PREVEDELLO, R. Effect of soil organic matter content, cover crop and planting system on the control of Pratylenchus brachyurus in soybean. Summa phytopathol, 40: 63-70, 2014.
DIAS, W. P. et al. Nematoides em Soja: Identificação e Controle Londrina, PR: Embrapa Soja, 2010. 8 p. (Circular Técnica 76).
FRANCHINI, J. C. et al. Perda de produtividade da soja em área infestada por nematoide das lesões radiculares na região médio norte do Mato Grosso. In: BERNARDI, A. C. C. et al. (Eds.). Agricultura de precisão: resultados de um novo olhar Brasília, DF: Embrapa, 2014. v. 1. , cap. 24, p. 274-278.
GOULART, A. M. C. Aspectos Gerais Sobre Nematoides-das-lesões-radiculares (Gênero Pratylenchus) 1 ed., Planaltina, DF: Embrapa Cerrados, 2008. 27 p.
HUSSEY, R. S.; BARKER, K. R. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Disease Reporter, 57: 1025-1028, 1973.
JOHNSON, A. W. Specific crop rotation practices combined with cultural practices and nematcides. An Advanced Treatise on Meloidogyne v. 1. Biology and control, 1: 283–301, 1985.
OLIVEIRA, K. C. L. et al. Biological management of Pratylenchus brachyurus in soybean crops. Revista Caatinga, 32: 41-51, 2019.
SILVA, R. A. et al. Reação de cultivares de Brachiaria spp. a Pratylenchus brachyurus Revista Connection Line, 9: 122–129, 2013.
SILVA, R. A. Manejo integrado de fitonematoides em soja e algodão. Revista Cultivar: Programas de aplicações, 201: 45-50, 2016.
SILVA, R. A. et al. Efeito da Rotação de culturas no manejo de nematoides em áreas arenosa. Nematropica, 48: 198-206, 2018.
WANG, K. H.; SIPES, B. S.; SCHMITT, D. P. Crotalaria as a cover crop for nematode management: a review. Department of Plant and Environmental Protection Sciences University of Hawaii, Honolulu, U.S.A. Nematropica, 32: 35-57, 2002.

Publication Dates

Publication in this collection
22 May 2023
Date of issue
Apr-Jun 2023

History

Received
07 June 2021
Accepted
13 Oct 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ALCANFOR, D. C. et al. Controle de nematóides de galhas com produtos naturais. Horticultura Brasileira, 19: Suplemento - CD ROM, 2001.

[2] ARIEIRA, C. R. D. Bacillus: importante aliado no controle biológico de nematoides 2020. Disponível em: https://ilustrado.com.br/bacillus-importante-aliado-no-controle-biologico-de-nematoides. Acesso em: 20 out. 2022.
» https://ilustrado.com.br/bacillus-importante-aliado-no-controle-biologico-de-nematoides.

[3] BASYONY, A. G.; ABO-ZAID, G. A. Biocontrol of the rootknot nematode, Meloidogyne incognita, using an eco-friendly formulation from Bacillus subtilis, lab. and greenhouse studies. Egyptian Journal Biological Pest Control, 28: 1-13, 2018.

[4] BONETI, J. I. S.; FERRAZ, S. Modificação do método de Hussey e Barker para extração de ovos de Meloidogyne exigua de raízes de cafeeiro. Fitopatologia Brasileira, 6: 553-553, 1981.

[5] CRUZ, T. T.; ASMUS, G. L.; GARCIA, R. A. Espécies de Crotalaria em sucessão à soja para o manejo de Pratylenchus brachyurus Ciencia Rural, 50: 1-8, 2020.

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[7] COSTA, M. J. N.; PASQUALLI, R. M.; PREVEDELLO, R. Effect of soil organic matter content, cover crop and planting system on the control of Pratylenchus brachyurus in soybean. Summa phytopathol, 40: 63-70, 2014.

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Treatments	Total nematode
Treatments	Without B. methylotrophicus	With B. methylotrophicus	% Reduction
Corn	28397 aB	36061 aA	−27
Millet ADRG 9050	19772 bA	19261 bB	35
Millet ADR 300	13217 dA	4120 eB	69
U. ruziziensis	17372 cA	8098 cB	53
C. ochroleuca	7622 eA	2923 fB	62
C. spectabilis	3778 fB	4446 dA	−18
	Nematode per gram of root
Corn	12860 bA	13303 aA	−3
Millet ADRG 9050	14710 aA	10681 fB	27
Millet ADR 300	7465 dA	2462 dB	67
U. ruziziensis	10931 cA	3637 cB	67
C. ochroleuca	2514 eA	1121 fB	55
C. spectabilis	1575 fA	1328 eB	16
p-value	<2.2 × 10⁻¹⁶

Treatments	Root fresh mass (g)
Corn DKB290	2.74 a
Millet ADRG 9050	1.87 b
Millet ADR 300	1.98 b
U. ruziziensis	2.37 b
C. ochroleuca	3.27 a
C. spectabilis	3.17 a
CV (%)	37.46

Treatments	With B. methylotrophic us	Without B. methylotrophic us	With B. methylotrophic us	Without B. methylotrophic us	% Reduction by B. methylotrophicus
Treatments	Total nematode		% Reduction of coverage concerning the control		% Reduction by B. methylotrophicus
Corn DKB 290	1262 eA	14521 aB	-	-	91.3
Millet ADRG 9050	1654 dB	1206 dA	-	91.7	-
Millet ADR 300	8527 aB	785 eA	-	94.6	-
U. ruziziensis	2527 cB	2236 cA	-	84.6	-
C. spectabilis	4844 bA	7331bB	-	49.5	33.9
p-value	2.2e⁻¹⁶
Treatments	Nematode/g of root		% Reduction of coverage concerning the control		% Reduction by B. methylotrophicus
Corn	88 eA	1301 bB	-	-	93.2
Millet ADRG 9050	180 dA	194 dA	-	85.1	7.0
Millet ADR 300	518 aB	117 eA	-	91.0	-
U. ruziziensis	287 cA	381 cB	-	70.1	24.7
C. spectabilis	367 bA	1765 aB	-	-	79.2
p-value	2.2e⁻¹⁶

Treatments	Total nematode
Treatments	Without B. subtilis	With B. subtilis	% Reduction
Corn	71817 aA	15712 bB	78
Millet ADRG 9050	14656 dA	11279 cB	23
Millet ADR 300	17388 cA	6543 dB	62
U. ruziziensis	41090 bA	17517 aB	57
C. ochroleuca	5790 eA	2194 eB	62
C. spectabilis 3263 fA	3263 fA	406 fB	88
	Nematode per gram of root
Corn	26198 aA	5295 bB	80
Millet ADRG 9050	6087 dA	5077 bB	17
Millet ADR 300	7541 cA	2176 cB	71
U. ruziziensis	20495 dA	5809 aB	72
C. ochroleuca	1315 eA	1064 dB	19
C. spectabilis	985 fA	201 eB	80
p-value	<2.2 × 10⁻¹⁶

Treatments	Root fresh mass (g) - With B. subtilis	Root fresh mass (g) - Without B. subtilis
Corn DKB 290	3.29 aA	2.51 bA
Millet ADRG 9050	2.25 aA	2.49 bA
Millet ADR 300	2.86 aA	2.58 bA
U. ruziziensis	2.66 aA	1.98 bA
C. ochroleuca	2.92 aB	4.09 aA
C. spectabilis	3.23 aA	3.35 aA
CV (%)	36.13

Experiments with Pratylenchus brachyurus
Treatments	Cover crops	Experiment 1	Experiment 2	U.F.C/seed
T1	Corn DKB 290	-	-	-
T2	Millet ADRG 9050	-	-	-
T3	Millet ADR 300	-	-	-
T4	U. ruziziensis	-	-	-
T5	C. ochroleuca	-	-	-
T6	C. spectabilis	-	-	-
T7	Corn DKB 290	B. methylotrophicus	B. subtilis	1×10⁶
T8	Millet ADRG 9050	B. methylotrophicus	B. subtilis	1×10⁶
T9	Millet ADR 300	B. methylotrophicus	B. subtilis	1×10⁶
T10	U. ruziziensis	B. methylotrophicus	B. subtilis	1×10⁶
T11	C. ochroleuca	B. methylotrophicus	B. subtilis	1×10⁶
T12	C. spectabilis	B. methylotrophicus	B. subtilis	1×10⁶
Experiments with Meloidogyne incognita
Treatments	Cover plant	Experiment 1	Experiment 2	U.F.C/seed
T1	Corn DKB 290	-	-	-
T2	Millet ADRG 9050	-	-	-
T3	Millet ADR 300	-	-	-
T4	U. ruziziensis	-	-	-
T5	C. spectabilis	-	-	-
T6	Corn DKB 290	B. methylotrophicus	B. subtilis	1×10⁶
T7	Millet ADRG 9050	B. methylotrophicus	B. subtilis	1×10⁶
T8	Millet ADR 300	B. methylotrophicus	B. subtilis	1×10⁶
T9	U. ruziziensis	B. methylotrophicus	B. subtilis	1×10⁶
T10	C. spectabilis	B. methylotrophicus	B. subtilis	1×10⁶

Brasil

Brasil

Cover crops and biocontrol agents in the management of nematodes in soybean crop

Plantas de cobertura e agentes de biocontrole no manejo de nematoides na cultura da soja

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History