Potential of aqueous extracts of basidiomycetes to control root-knot nematodes on lettuce

Wille, Caroline N; Gomes, Cesar B; Minotto, Elisandra; Nascimento, José S

doi:10.1590/S0102-053620190108

ABSTRACT

The root-knot nematode (Meloidogyne incognita) is one of the main pests of lettuce due to the crop’s high susceptibility, unavailability of registered nematicides and lack of resistant cultivars. The aim of this study was to evaluate the potential of aqueous extracts of ten basidiomycete fungi for root-knot nematode control (in vitro and in vivo) on lettuce. The aqueous extracts of these fungi were initially evaluated in vitro in relation to their nematostatic and nematicidal activity. All extracts inhibited the hatching of second-stage juveniles of nematodes. The extracts that provided the highest mortality index (Pleurotus ostreatus, P. citrinopileatus, P. pulmonarius and Boletus sp.) were applied in pots containing autoclaved and infested soil with root-knot nematode. After 24 h, one lettuce seedling (cv. Regina) per pot was transplanted using soil treated with distilled water as control. After 50 days, we observed that soil treated with fungal extracts reduced, approximately, 70% of nematode reproduction. Plants treated with extracts obtained higher fresh mass and extracts of Boletus sp. and P. pulmonarius reduced damages to roots, being considered as potential bio-controllers of this nematode.

Keywords:
Lactuca sativa; Meloidogyne incognita; Pleurotus spp.; Boletus sp.; biocontrol

RESUMO

Os nematoides das galhas (Meloidogyne incognita) estão entre as principais pragas da alface em função da elevada suscetibilidade da cultura, indisponibilidade de nematicidas e carência de cultivares resistentes. Foi objetivo deste trabalho, avaliar o potencial de extratos aquosos de dez diferentes basidiomicetos no controle de nematoides das galhas in vitro e in vivo na cultura da alface. Inicialmente os extratos foram avaliados in vitro quanto à atividade nematicida e nematostática. Todos os extratos inibiram a eclosão de juvenis de segundo estádio do nematoide. Os extratos que proporcionaram maiores índices de mortalidade (Pleurotus ostreatus, P. citrinopileatus, P. pulmonarius e Boletus sp.), foram aplicados em vasos com solo autoclavado e infestado com nematoides das galhas. Após 24 h, transplantou-se uma muda de alface cv. Regina por vaso, usando solo tratado com água destilada como testemunha. Decorridos 50 dias, verificou-se que o tratamento do solo com os extratos fúngicos reduziu, em média, 70% da reprodução do nematoide. As plantas tratadas com extratos obtiveram maior massa fresca e os extratos de Boletus sp. e P. pulmonarius reduziram os danos às raízes, sendo considerados potenciais biocontroladores desse nematoide.

Palavras-chave:
Lactuca sativa; Meloidogyne incognita; Pleurotus spp.; Boletus sp.; biocontrole

Lettuce (Lactuca sativa) is the most consumed leafy vegetable in Brazil (ABCSEM, 2016ABCSEM - Associação Brasileira do Comércio de Sementes e Mudas. October 5, 2016. O mercado de folhosas, números e tendências, divulgação do projeto para o levantamento dos dados socioeconômicos da cadeia produtiva de hortaliças no Brasil. Available at http://www.abcsem.com.br/upload/arquivos/O_mercado_de_folhosas__Numeros_e_Tendencias_-_Steven.pdf
http://www.abcsem.com.br/upload/arquivos... ) and is of great economic importance (Lima et al., 2008LIMA, JD; MORAES, WS; SILVA, SHMG; IBRAHIM, FN. 2008. Acúmulo de compostos nitrogenados e atividade da redutase do nitrato em alface produzida sob diferentes sistemas de cultivo. Pesquisa Agropecuária Tropical 38: 180-187.), mainly for family farming, since this crop is grown in small areas and contributes for generating direct jobs. Due to the high perishability of this vegetable, lettuce is grown in small areas near consumption centers in consecutive plantations all over the year (Henz & Suinaga, 2009HENZ, GP; SUINAGA, F. 2009. Tipos de alface cultivados no Brasil. Comunicado Técnico 75. Embrapa Hortaliças.).

The intensive use of the soil, under monoculture system, promotes one of the main phytosanitary problems of lettuce crop, as for example the nematodes of genus Meloidogyne (Wilcken et al., 2004WILCKEN, SRS; GARCIA, MJM; SILVA, N. 2004. Reprodução de Meloidogyne incognita raça 2 em diferentes cultivares de alface (Lactuca sativa L.). Arquivos do Instituto Biológico 71: 379-381.). High infestation of root-knot nematodes reduces quantity and quality of the harvested product (Santos, 1995SANTOS, HS. 1995. Efeitos de sistemas de manejo do solo e de métodos de plantio na produção de alface (Lactuca sativa L.) em abrigo com solo naturalmente infestado com Meloidogyne javanica. Lavras: Universidade Federal de Lavras. 88p. (Ph.D. thesis).) and, considering the soil texture, it can cause host death (Prakob et al., 2009PRAKOB, W; HOM, JN; SILAPAPONGPRI, PJS; THANUNCHAI, J; CHAISUK, P. 2009. Biological control of lettuce root-knot disease by the used of Pseudomonas aeruginosa, Bacillus subtilis and Paecilomyces lilacinus. Journal of Agricultural Technology 5: 179-191.).

In Brazil, M. incognita and M. javanica are the species of greatest incidence on lettuce-producing regions (Pinheiro et al., 2013PINHEIRO, JB; PEREIRA, RB; CARVALHO, ADF; RODRIGUES, CS; SUINAGA, FA. 2013. Manejo de nematoides na cultura da alface. Circular Técnica. Embrapa Hortaliças, 8p.). Although the management of these species is essential, it presents several difficulties, since there are no registered chemicals for nematode control for the crop (AGROFIT, 2017AGROFIT: Sistema de Agrotóxicos Fitossanitários. August 23, 2017. Ministério da Agricultura, Pecuária e Abastecimento - Coordenação-Geral de Agrotóxicos e Afins/DFIA/DAS. Available at http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons.
http://agrofit.agricultura.gov.br/agrofi... ). The majority of commercial cultivars is susceptible and, crop rotation, besides presenting resistance of farmers due to the low availability of productive area, must be careful, since most of the cultivated plant species can be infected by these pathogens (Dias et al., 2007DIAS, WP; RIBEIRO, NR; LOPES, ION; GARCIA, A; CARNEIRO, GES; SILVA, JFV. 2007. Manejo de nematoides na cultura da soja. In: CONGRESSO BRASILEIRO DE NEMATOLOGIA, 27. Goiânia. Anais... Goiânia. p.26-30.).

Thus, evaluating alternative strategies, such as biological control, in order to make production in areas infested with these pathogens viable, is essential. In this context, the fungi are among the main biological agents used in the management of phytoparasitic nematodes (Li et al., 2007LI, G; ZHANG, K; XU, J; DONG, J; LIU, Y. 2007. Nematicidal substances from fungi. Recent Patents on Biotechnology 3: 12-23.), including Meloidogyne species (Swe, 2011SWE, A; LI, J; ZHANG, KQ; POINTING, SB; JEEWON, R; HYDE, KD. 2011. Nematode-trapping fungi. Current Research in Environmental & Applied Mycology 1: 1-26.; Degenkolb & Vilcinskas, 2016aDEGENKOLB, T; VILCINSKAS, A. 2016a. Metabolites from nematophagous fungi and nematicidal natural products from fungi as an alternative for biological control. Part I: metabolites from nematophagous ascomycetes. Applied Microbiololy and Biotechnololy 100: 3799-3812.,b). Besides acting as natural enemies capturing and parasiting nematodes (Goswami et al., 2006GOSWAMI, BK; PANDEY, RK; RATHOUR, KS; BHATTACHARYA, C; SINGH, L. 2006. Integrated application of some compatible biocontrol agents along with mustard oil seed cake and furadan on Meloidogyne incognita infecting tomato plants. Journal of Zhejiang University Science B7: 873-875.; Haseeb & Kumar, 2006HASEEB, A; KUMAR, V. 2006. Management of Meloidogyne incognita - Fusarium solani disease complex in brinjal by biological control agents and organic additives. Annals of Plant Protection Sciences 14: 519-521.; Swe et al., 2011), these organisms are able to produce several antagonistic substances (Tranier et al., 2014TRANIER, MS; GROS, JP; QUEIROZ, RC; GONZÁLEZ, CNA; MATEILLE, T; ROUSSOS, S. 2014. Commercial biopesticides against plant parasitic nematodes. Brazilian Archives of Biology and Technology 57: 831-841.; Degenkolb & Vilcinskas; 2016aDEGENKOLB, T; VILCINSKAS, A. 2016b. Metabolites from nematophagous fungi and nematicidal natural products from fungi as alternatives for biological control. Part II: metabolites from nematophagous basidiomycetes and non-nematophagous fungi. Applied Microbiology and Biotechnology 100: 3813-3824.). Several nematicidal-action substances were isolated from basidiomycetes, including different fatty acids produced by species of Pleurotus (Li et al., 2007LI, G; ZHANG, K; XU, J; DONG, J; LIU, Y. 2007. Nematicidal substances from fungi. Recent Patents on Biotechnology 3: 12-23.); the efficiency of these fungi was previously demonstrated, reducing galls on tomato plants (Putzke et al., 2007PUTZKE, MTL; MATSUMURA, ATS; CAVALCANTI, MAQ; C-FILHO, A. 2007. Taxonomia e importância das espécies de Hohenbuehelia resupinatus e Pleurotus no controle de Meloidogyne javanica. Caderno de Pesquisa série Biologia Universidade de Santa Cruz do Sul 19: 38-81.).

Some studies about formulations using vegetative mycelium of basidiomycetes have been highlighted. However, activity, concentration and diversity of compounds in fungi are generally higher in fructification bodies compared to the ones observed in mycelium (Tidke & Raí, 2006TIDKE, G; RAI, M. 2006. Biotechnological potential of mushrooms: drugs and dye production. International Journal of Medicinal Mushrooms 8: 351-360.).

Given the above, we aimed to evaluate the in vitro potential of different mushroom extracts on M. incognita biocontrol, select the best isolates for in vivo test and evaluate the efficiency of water extracts previously selected, for M. incognita biocontrol on lettuce crop, under greenhouse conditions.

MATERIAL AND METHODS

Obtaining aqueous extracts

The mushrooms Pleurotus ostreatus, P. ostreatoroseus, P. citrinopileatus, P. sajor-caju and P. pulmonarius were grown in Laboratório de Micologia do Departamento de Microbiologia e Parasitologia do Instituto de Biologia of Universidade Federal de Pelotas. These fungi belong to the collection of the laboratory and were grown following severely pasteurized substrate technique (Bernardi, 2007BERNARDI, E. 2007. Cultivo de Pleurotus em substrato capim elefante (Pennisetum purpureum Shum) pasteurizado. Pelotas: UFPEL-FAEM. 81p. (M.Sc. tesis).). Other mushrooms used were Amanita muscaria, Boletus sp., Lactarius deliciosus, Russula amethystina and Suillus sp.. These were collected from May to August, 2009 at UFPel Campus and Embrapa Clima Temperado, in Pelotas. These mushrooms were identified in the laboratory, observing fruiting body morphological traits. After harvest, basidioms were washed and dehydrated (35°C for 15 days) in the laboratory.

In order to prepare aqueous extracts, the authors followed adapted cold extraction methodology (Fiori-Tutida et al., 2007FIORI-TUTIDA, ACG; ESTRADA, KRFS; STANGARLIN, JR; PASCHOLATI, SF. 2007. Extratos de Lentinu laedodes e Agaricus blazei sobre Bipolaris sorokiniana e Puccinia recondita f. sp. tritici, in vitro. Summa Phytopathologica 33: 113-118.). Dry mushrooms were ground in proportion of 50 g of mushroom/L distilled water. The mixture was kept under refrigeration at 4ºC for 24 hours and, then, filtered through cotton, followed by centrifugation at 5,000 RPM, at 4°C, for one hour. The supernatant was filtered through Whatman # 1 filter, 0.45 and 0.25 μm cellulose acetate membranes, respectively. Finally, the last step was carried out under aseptic conditions in a laminar flow chamber. Extracts were tested within a maximum period of 24 hours after preparation.

Inoculum of M. incognita

A pure population of Meloidogyne incognita was multiplied and kept in tomato crop cv. Santa Cruz in greenhouse (Carneiro & Almeida, 2001CARNEIRO, RMD; ALMEIDA, MRA. 2001. Técnica de eletroforese usada no estudo de enzimas dos nematoides de galhas para identificação de espécie. Nematologia Brasileira 25: 35-44.). Eggs and second-stage juveniles (J2) of M. incognita were obtained according to Hussey & Barker technique (1973HUSSEY, RS; BARKER, KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Disease Report 57: 1025-1028.). Second-stage juveniles (J2), used in in vitro tests, were extracted from roots infected with nematodes by a modified Baermann funnel technique (Christie & Perry, 1951CHRISTIE, JR; PERRY, VG. 1951. Removing nematodes from soil. Proceedings of Helminthological Society of Washington 18: 106-108.).

In vitro tests

The nematicidal activity of extracts was obtained in an assay conducted on Elisa plates, four replications per treatment, in a randomized complete block design, considering each replication represented by a plate cavity containing 25 J2 of M. incognita. The mortality was tested through the modified methodology described by Ludwig et al. (2013LUDWIG, J; MOURA, AB; GOMES, CB. 2013. Potencial da microbiolização de sementes de arroz com rizobactérias para o biocontrole do nematoide das galhas. Tropical Plant Pathology 38: 264-268.). Each Elisa plate cavity was covered with a 20 µL aliquot of distilled water containing J2 of nematode. Then, 80 µL of aqueous extracts of each basidiomycete was added, except for the control, in which just distilled water was used. Afterwards, the plates were sealed with plastic film and kept in a BOD incubator at 25°C in the dark. After 24-hour incubation, in each plate cavity, 10 µL of NaOH 1N at 1% was added adapting the methodology proposed by Chen et al. (2000CHEN, SY; DICKSON, DW; MITCHELL, DJ. 2000. Viability of Heterodera glycines exposed to fungal filtrates. Journal of Nematology 32: 190-197.), in which the number of dead and alive juveniles was evaluated. We considered dead the J2 whose body remained completely distended for one minute after adding NaOH, during evaluations under stereoscopic microscope.

Data on the percentage of dead J2 were transformed to arcsine using comparisons of treatment means by Scott-Knott test at 5% probability using SASM- AGRI program (Canteri et al., 2001CANTERI, MG; ALTHAUS, RA; VIRGENS FILHO, JS; GIGLIOTI, EA; GODOY, CV. 2001. SASM-AGRI - sistema para análise e separação de médias em experimentos agrícolas pelos métodos Scott-Knott, Tukey e Duncan. Revista Brasileira de Agrocomputação 2: 18-24.).

To verify the effect of extracts on J2 nematode outbreaks, an Elisa assay was installed, similarly to the mortality assay previously described. In this case, a 20 µL aliquot of distilled water containing approximately 25 eggs was put in each plate cavity, adding J2 nematodes, adding 80 µL of aqueous extracts of mushroom and distilled water on the control. Then, the plates were covered with plastic film and kept in a BOD incubator in the dark for 12 days. After incubation, the number of hatching juveniles and remaining eggs was evaluated, to determine hatching percentage of J2 of M. incognita. The percentage was obtained using the formula:

hatching (%) = (number of juveniles)/(number of juveniles+remaining eggs) x 100.

Then, treatment averages were compared among each other by Scott Knott group test at 5% probability using SASM- AGRI program (Canteri et al., 2001CANTERI, MG; ALTHAUS, RA; VIRGENS FILHO, JS; GIGLIOTI, EA; GODOY, CV. 2001. SASM-AGRI - sistema para análise e separação de médias em experimentos agrícolas pelos métodos Scott-Knott, Tukey e Duncan. Revista Brasileira de Agrocomputação 2: 18-24.).

Effect of fungi extracts on control of M. incognita in lettuce crop

According to the obtained results in in vitro tests, mushrooms whose extracts caused higher percentage of juvenile mortality of M. incognita were selected.

To simulate the use of mushroom extracts in treatment of pre-cultivation soil on lettuce, autoclaved soil (121ºC for 2 hours) was kept in a greenhouse for five days, homogenized, evaluated in relation to field capacity and fractioned into portions of two kilos. Each soil fraction was kept in a plastic bag, with 100 mL water, 18 mL of mushroom extract (10% p/v) and 1.5 mL of eggs suspension containing 5,000 eggs + J2 of M. incognita obtained from infested tomato roots, according to Hussey & Barker (1973HUSSEY, RS; BARKER, KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Disease Report 57: 1025-1028.). Afterwards, soil was homogenized, transferred to pots and covered with plastic film.

For control treatments, pots with autoclaved soil treated with distilled water and with or without nematode infestation were used. One lettuce seedling, cultivar ‘Regina’, was transferred to the center of each pot, 24 h after treatment application. Subsequently all pots were kept in a greenhouse at 25+3ºC. The experiment consisted of six replications (pots) per treatment distributed in a completely randomized design.

Fifty days after inoculation, lettuce plants were removed from the soil, and shoot fresh mass determined using a semi-analytical scale; roots were carefully washed and root fresh mass, number of galls and damage level were evaluated according to the scale proposed by Zech (1971ZECH, WM. 1971. A rating scheme for field evaluation of root- knot nematode infestations. Pflanzenschutz Nachrichten 24: 141-144.), being scored from 0 to 10, according to visual inferences in relation to number of galls and severity symptoms caused by nematodes in the plant. Grade 0 corresponded to the plant with no infection and 10 to the dead plant. Right after, the roots of each plant were chopped and grinded in a blender with 0.5% hypochlorite solution for extraction of M. incognita (Hussey & Barker, 1973HUSSEY, RS; BARKER, KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Disease Report 57: 1025-1028.). Total number of eggs and J2 in roots were determined and the reproduction factor of M. incognita per plant (final population / initial population), related to each replication was calculated (Oostenbrink, 1966OOSTENBRINK, M. 1966. Major characteristics of the relation between nematodes and plants. Meded. Landbouwhogeschool. Wageningen 66: 3-46.), estimating the control percentage in each treatment. Treatment averages were compared among each other using Duncan test at 5% probability using SASM- AGRI program (Canteri et al., 2001CANTERI, MG; ALTHAUS, RA; VIRGENS FILHO, JS; GIGLIOTI, EA; GODOY, CV. 2001. SASM-AGRI - sistema para análise e separação de médias em experimentos agrícolas pelos métodos Scott-Knott, Tukey e Duncan. Revista Brasileira de Agrocomputação 2: 18-24.).

RESULTS AND DISCUSSION

All evaluated fungal extracts showed some nematostatic and nematicidal activity against eggs and J2 of M. incognita, respectively, in relation to control (Table 1), in the in vitro tests.

The nematicidal effect of fungi on nematode presented mortality indexes ranging from 90.7 to 100% on different treatments. However, the extracts of P. ostreatus, Boletus sp., P. pulmonarius and P. citrinopileatus provided the highest percentage of dead nematodes (Table 1). Thus, these four isolates were selected to evaluate the potential for biological control of M. incognita in lettuce crop, in greenhouse.

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Table 1
Effect of aqueous extract from ten basidiomycete fungi on hatching and mortality (%) of J2 Meloidogyne incognita. Pelotas, Embrapa Clima Temperado, 2018.

The extract potential for controlling nematodes was proved in in vivo tests, in which suppressed the reproduction of M. incognita and provided the highest values of fresh mass of lettuce plants. Damage severity in lettuce was significantly reduced only with extracts of Boletus sp. and P. pulmonarius. Nevertheless, the number of eggs and reproduction factor of M. incognita were significantly lower in comparison to the control in all treatments (Table 2), showing the efficiency of mushroom extracts, evaluated in this study, on root-knot nematode control.

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Table 2
Effect of aqueous extract of dried mushrooms on level of damage, control and reproduction of Meloidogyne incognita on lettuce cv. Regina cultivar under greenhouse conditions. Pelotas, Embrapa Clima Temperado, 2018.

Nematode control using mushroom extracts achieved an average reduction of nematode reproduction of 62%, compared to the control group, which may have favored the development of plants expressed by an increase of shoot fresh mass (Table 3), being this yield statistically similar to the plants grown without nematodes (Table 3).

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Table 3
Effect of aqueous extracts of dried mushrooms on shoot fresh mass (MFPA) and root fresh mass (MFR) of lettuce plants cv. Regina in soil infested with M. incognita. Pelotas, Embrapa Clima Temperado, 2017.

Although the aqueous extracts did not affect root fresh mass (Table 3), soil treatment using P. pulmonarius and Boletus sp. extracts, resulted in lower levels of damaged roots of lettuce (Table 2). Thus, these treatments evidenced the main objective of the use of alternative methods with biological control agents which is damage reduction since the yield of plants grown in a soil treated with extracts was similar to those ones observed in plants grown without nematodes (Table 3).

The use of basidiomycetes may contribute to the phytoparasitc nematodes control a great deal. In this sense, basidiomycetes may affect motility and capacity of penetration of active forms into plants, the attraction of the juvenile by the host, interfering in their hatching or causing the death of these phytoparasites (Kulkarni & Sangita, 2000KULKARNI, SM; SANGIT, AD. 2000. Cultivation of Hohenbuehelia atrocaerulea (Fr.) Sing. (Agaricomycetideae): a mushroom with nematicidal potential. International Journal of Medicinal Mushrooms 2: 161-163.; Hong et al., 2007HONG, L; LIU, Y; FANG, L; LI, X; TANG, N.; ZHANG, K. 2007.Coprinus comatus damages nematode cuticles mechanically with spiny balls and produces potent toxins to immobilize nematodes. Applied and Environmental Microbiology 73: 3916-3923.). Although toxic to nematodes, most fungal compounds present in the basidiocarp have a selective effect, since they preserve non-target species, showing the possibility to develop products which are safer to the environment (Li et al., 2007LI, G; ZHANG, K; XU, J; DONG, J; LIU, Y. 2007. Nematicidal substances from fungi. Recent Patents on Biotechnology 3: 12-23.).

The potential of several mushrooms of the genus Pleurotus was also showed, controlling M. javanica, in vitro, in studies demonstrating the presence of specialized structures in vegetative mycelium which secrete substances able to immobilize nematodes (Heydari et al., 2006HEYDARI, R; POURJAM, E; GOLTAPEH, EM. 2006. Antagonistic effect of some species of Pleurotus on the root-knot nematode, Meloidogyne javanica in vitro. Plant Pathology Journal 5: 173-177.). Besides, studies on nematode Panagrellu ssp. demonstrated that P. ostreatus provides different enzymes which may contribute directly to biological control of phytonematoids (Genier et al., 2015GENIER, HLA; SOARES, FEF; QUEIROZ, JH; GOUVEIA, AS; ARAÚJO, JV; BRAGA, FR; PINHEIRO, IR; KASUYA, MCM. 2015. Activity of the fungus Pleurotus ostreatus and of its proteases on Panagrellus sp. larvae. African Journal of Biotechnology 14: 1497-1503.). Although specialized structures against nematodes are reported in vegetative stage, basidioms or mushrooms are known for the diversity of secondary metabolites with a broad spectrum of biological activities exploited in traditional medicines (Ganeshpurkar & Jain, 2010GANESHPURKARARAI, G, JAIN, AP. 2010. Medicinal mushrooms: Towards a new horizon. Pharmacognosy Review 4: 127-135.).

Hatching inhibition potential or nematicidal effect on J2 of M. incognita was confirmed in the in vivo evaluation, in which the extract of P. ostreatus reduced reproduction factor of M. incognita in lettuce by more than 70%. The efficiency of Pleurotus spp. to control nematodes was also demonstrated in other studies, emphasizing the importance of further studies. Pleurotus sajor-caju was used to control mycophagous nematodes which affect the production of champignon (Agaricus bisporus), in which the application of residue extract of P. sajor-caju in the substrate reduced population of Aphelenchoides composticola in 90% (Sharma, 1994SHARMA, VP. 1994. Potential of Pleurotus sajor-caju for biocontrol of Aphelenchoides camposticola in Agaricus bisporus cultivation. Mushroom Research 3: 15-20.). In another study, the application of substrate colonized by P. ostreatus and P. ostreatoroseus in soil, provided 70% reduction in the number of galls caused by M. javanica in tomato (Putzke et al., 2007PUTZKE, MTL; MATSUMURA, ATS; CAVALCANTI, MAQ; C-FILHO, A. 2007. Taxonomia e importância das espécies de Hohenbuehelia resupinatus e Pleurotus no controle de Meloidogyne javanica. Caderno de Pesquisa série Biologia Universidade de Santa Cruz do Sul 19: 38-81.).

The effect of Pleurotus spp. was also described in controlling M. incognita in soybean, reporting reduction of number of galls and promotion of plant growth, as well as an increase in number of rhizobium nodules (Okorie et al., 2011OKORIE, CC; ONONUJU, CC; OKWUJIAKO, IA. 2011.Management of Meloidogyne incognita with Pleurotus ostreatus and P. tuberregium in soybean. International Journal of Agriculture and Biology 13: 401-405.), showing, similarly to this study, that the treatment with mushroom can suppress M. incognita.

In addition to the reduction of reproduction factor of nematodes, fungal treatments resulted in reduction of M. incognita damage up to two levels on Zech scale. Marino & Silva (2013MARINO, RH; SILVA, DGC. 2013. Controle do nematoide-das-galhas por Pleurotus ostreatus em alface. Scientia Plena 9: 1-6.), evaluating isolates of P. ostreatus containing coconut powder to control M. incognita on lettuce, verified reduction of number of galls and egg masses up to 90%. Similarly, other authors tested different substrates for soil biofumigation in biological control of M. incognita on tomato crop and showed that residue of P. ostreatus reduced in 70% nematode population density (El-Sherbiny & Awd-Allah, 2014)EL-SHERBINY, AA; AWD ALLAH, SFA. 2014. Management of the root-knot nematode, Meloidogyne incognita on tomato plants by pre-planting soil biofumigation harvesting residues of some winter crops and waste residues of oyster mushroom cultivation under field conditions. Egyptian Journal of Agronematology 13: 189-202., as observed in this study.

Moreover, fungal potential was verified in experiments with violets, in which application of substrate containing P. ostreatus mycelium suppressed M. javanica (Abbasi et al., 2014ABBASI, N.; MOHAMMADI TORKASHVAN, A.; RAHANANDEH, H. 2014. Evaluation of mushroom compost for the bio control root-knot nematode. International Journal of Biociences 5: 147-153.). Besides, application of 500 g of substrate containing P. ostreatus for each cubic meter of soil was able to reduce M. incognita and Heterodera goldeni population on rice plants, above 80%, surpassing treatments with Bacillus thuringiensis and obtaining almost the same result using nematicide Oxamyl (Awd-Allah & El-Sherbiny, 2015AWD-ALLAH, SF; EL-SHERBINY, AA. 2015. Non chemical control of Heterodera goldeni and Meloidogyne incognita on rice plants using residues of oyster mushroom cultivation and supernatant of Bacillus thuringiensis before transplanting under field microplots conditions. Egypt Journal of agronematology 14: 62-77.).

Although several studies demonstrate the efficiency of basidiomycetes in the control of plant parasitic nematodes, formulations obtained from vegetative phase of fungi are frequently used. However, activity, concentration and diversity of compounds in fungi are generally higher in fructification bodies compared with the ones observed in mycelium (Tidke & Raí, 2006TIDKE, G; RAI, M. 2006. Biotechnological potential of mushrooms: drugs and dye production. International Journal of Medicinal Mushrooms 8: 351-360.).

The selected mushrooms for in vivo evaluation, such as Pleurotus spp., are edible; so they are cultivated and commercially exploited (Ramos et al., 2011RAMOS, C; SAPATA, M; FERREIRA, A; ANDRADA, L; CANDEIAS, M. 2011. Produção de três espécies de cogumelos Pleurotus e avaliação da qualidade em atmosfera modificada. Revista de Ciências Agrárias 34: 57-64.). That is why, evaluating basidioms as an alternative for pest control, considering both efficiency and possibility to use the residue, generated by the edible mushroom industry, is so important.

Extracts of basidiomycete fungi may represent a promising management strategy in relation to existing difficulties for phytoparasitic nematodes management in lettuce crop. However, the importance of its use in integrated management approach must be considered, combining other control techniques in order to suppress this pest and also provide an increase in production and quality of lettuce.

ACKNOWLEGMENTS

The authors thank Embrapa for providing resources for this experiment and Capes for post-graduation scholarships during this project development.

REFERENCES

ABBASI, N.; MOHAMMADI TORKASHVAN, A.; RAHANANDEH, H. 2014. Evaluation of mushroom compost for the bio control root-knot nematode. International Journal of Biociences 5: 147-153.
ABCSEM - Associação Brasileira do Comércio de Sementes e Mudas. October 5, 2016. O mercado de folhosas, números e tendências, divulgação do projeto para o levantamento dos dados socioeconômicos da cadeia produtiva de hortaliças no Brasil. Available at http://www.abcsem.com.br/upload/arquivos/O_mercado_de_folhosas__Numeros_e_Tendencias_-_Steven.pdf
» http://www.abcsem.com.br/upload/arquivos/O_mercado_de_folhosas__Numeros_e_Tendencias_-_Steven.pdf
AGROFIT: Sistema de Agrotóxicos Fitossanitários. August 23, 2017. Ministério da Agricultura, Pecuária e Abastecimento - Coordenação-Geral de Agrotóxicos e Afins/DFIA/DAS. Available at http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons
» http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons
AWD-ALLAH, SF; EL-SHERBINY, AA. 2015. Non chemical control of Heterodera goldeni and Meloidogyne incognita on rice plants using residues of oyster mushroom cultivation and supernatant of Bacillus thuringiensis before transplanting under field microplots conditions. Egypt Journal of agronematology 14: 62-77.
BERNARDI, E. 2007. Cultivo de Pleurotus em substrato capim elefante (Pennisetum purpureum Shum) pasteurizado. Pelotas: UFPEL-FAEM. 81p. (M.Sc. tesis).
CANTERI, MG; ALTHAUS, RA; VIRGENS FILHO, JS; GIGLIOTI, EA; GODOY, CV. 2001. SASM-AGRI - sistema para análise e separação de médias em experimentos agrícolas pelos métodos Scott-Knott, Tukey e Duncan. Revista Brasileira de Agrocomputação 2: 18-24.
CARNEIRO, RMD; ALMEIDA, MRA. 2001. Técnica de eletroforese usada no estudo de enzimas dos nematoides de galhas para identificação de espécie. Nematologia Brasileira 25: 35-44.
CHEN, SY; DICKSON, DW; MITCHELL, DJ. 2000. Viability of Heterodera glycines exposed to fungal filtrates. Journal of Nematology 32: 190-197.
CHRISTIE, JR; PERRY, VG. 1951. Removing nematodes from soil. Proceedings of Helminthological Society of Washington 18: 106-108.
DEGENKOLB, T; VILCINSKAS, A. 2016a. Metabolites from nematophagous fungi and nematicidal natural products from fungi as an alternative for biological control. Part I: metabolites from nematophagous ascomycetes. Applied Microbiololy and Biotechnololy 100: 3799-3812.
DEGENKOLB, T; VILCINSKAS, A. 2016b. Metabolites from nematophagous fungi and nematicidal natural products from fungi as alternatives for biological control. Part II: metabolites from nematophagous basidiomycetes and non-nematophagous fungi. Applied Microbiology and Biotechnology 100: 3813-3824.
DIAS, WP; RIBEIRO, NR; LOPES, ION; GARCIA, A; CARNEIRO, GES; SILVA, JFV. 2007. Manejo de nematoides na cultura da soja. In: CONGRESSO BRASILEIRO DE NEMATOLOGIA, 27. Goiânia. Anais... Goiânia. p.26-30.
EL-SHERBINY, AA; AWD ALLAH, SFA. 2014. Management of the root-knot nematode, Meloidogyne incognita on tomato plants by pre-planting soil biofumigation harvesting residues of some winter crops and waste residues of oyster mushroom cultivation under field conditions. Egyptian Journal of Agronematology 13: 189-202.
FIORI-TUTIDA, ACG; ESTRADA, KRFS; STANGARLIN, JR; PASCHOLATI, SF. 2007. Extratos de Lentinu laedodes e Agaricus blazei sobre Bipolaris sorokiniana e Puccinia recondita f. sp. tritici, in vitro. Summa Phytopathologica 33: 113-118.
GANESHPURKARARAI, G, JAIN, AP. 2010. Medicinal mushrooms: Towards a new horizon. Pharmacognosy Review 4: 127-135.
GENIER, HLA; SOARES, FEF; QUEIROZ, JH; GOUVEIA, AS; ARAÚJO, JV; BRAGA, FR; PINHEIRO, IR; KASUYA, MCM. 2015. Activity of the fungus Pleurotus ostreatus and of its proteases on Panagrellus sp. larvae. African Journal of Biotechnology 14: 1497-1503.
GOSWAMI, BK; PANDEY, RK; RATHOUR, KS; BHATTACHARYA, C; SINGH, L. 2006. Integrated application of some compatible biocontrol agents along with mustard oil seed cake and furadan on Meloidogyne incognita infecting tomato plants. Journal of Zhejiang University Science B7: 873-875.
HASEEB, A; KUMAR, V. 2006. Management of Meloidogyne incognita - Fusarium solani disease complex in brinjal by biological control agents and organic additives. Annals of Plant Protection Sciences 14: 519-521.
HENZ, GP; SUINAGA, F. 2009. Tipos de alface cultivados no Brasil. Comunicado Técnico 75. Embrapa Hortaliças.
HEYDARI, R; POURJAM, E; GOLTAPEH, EM. 2006. Antagonistic effect of some species of Pleurotus on the root-knot nematode, Meloidogyne javanica in vitro. Plant Pathology Journal 5: 173-177.
HONG, L; LIU, Y; FANG, L; LI, X; TANG, N.; ZHANG, K. 2007.Coprinus comatus damages nematode cuticles mechanically with spiny balls and produces potent toxins to immobilize nematodes. Applied and Environmental Microbiology 73: 3916-3923.
HUSSEY, RS; BARKER, KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Disease Report 57: 1025-1028.
KULKARNI, SM; SANGIT, AD. 2000. Cultivation of Hohenbuehelia atrocaerulea (Fr.) Sing. (Agaricomycetideae): a mushroom with nematicidal potential. International Journal of Medicinal Mushrooms 2: 161-163.
LI, G; ZHANG, K; XU, J; DONG, J; LIU, Y. 2007. Nematicidal substances from fungi. Recent Patents on Biotechnology 3: 12-23.
LIMA, JD; MORAES, WS; SILVA, SHMG; IBRAHIM, FN. 2008. Acúmulo de compostos nitrogenados e atividade da redutase do nitrato em alface produzida sob diferentes sistemas de cultivo. Pesquisa Agropecuária Tropical 38: 180-187.
LUDWIG, J; MOURA, AB; GOMES, CB. 2013. Potencial da microbiolização de sementes de arroz com rizobactérias para o biocontrole do nematoide das galhas. Tropical Plant Pathology 38: 264-268.
MARINO, RH; SILVA, DGC. 2013. Controle do nematoide-das-galhas por Pleurotus ostreatus em alface. Scientia Plena 9: 1-6.
OKORIE, CC; ONONUJU, CC; OKWUJIAKO, IA. 2011.Management of Meloidogyne incognita with Pleurotus ostreatus and P. tuberregium in soybean. International Journal of Agriculture and Biology 13: 401-405.
OOSTENBRINK, M. 1966. Major characteristics of the relation between nematodes and plants. Meded. Landbouwhogeschool. Wageningen 66: 3-46.
PINHEIRO, JB; PEREIRA, RB; CARVALHO, ADF; RODRIGUES, CS; SUINAGA, FA. 2013. Manejo de nematoides na cultura da alface. Circular Técnica. Embrapa Hortaliças, 8p.
PRAKOB, W; HOM, JN; SILAPAPONGPRI, PJS; THANUNCHAI, J; CHAISUK, P. 2009. Biological control of lettuce root-knot disease by the used of Pseudomonas aeruginosa, Bacillus subtilis and Paecilomyces lilacinus. Journal of Agricultural Technology 5: 179-191.
PUTZKE, MTL; MATSUMURA, ATS; CAVALCANTI, MAQ; C-FILHO, A. 2007. Taxonomia e importância das espécies de Hohenbuehelia resupinatus e Pleurotus no controle de Meloidogyne javanica. Caderno de Pesquisa série Biologia Universidade de Santa Cruz do Sul 19: 38-81.
RAMOS, C; SAPATA, M; FERREIRA, A; ANDRADA, L; CANDEIAS, M. 2011. Produção de três espécies de cogumelos Pleurotus e avaliação da qualidade em atmosfera modificada. Revista de Ciências Agrárias 34: 57-64.
SANTOS, HS. 1995. Efeitos de sistemas de manejo do solo e de métodos de plantio na produção de alface (Lactuca sativa L.) em abrigo com solo naturalmente infestado com Meloidogyne javanica. Lavras: Universidade Federal de Lavras. 88p. (Ph.D. thesis).
SHARMA, VP. 1994. Potential of Pleurotus sajor-caju for biocontrol of Aphelenchoides camposticola in Agaricus bisporus cultivation. Mushroom Research 3: 15-20.
SWE, A; LI, J; ZHANG, KQ; POINTING, SB; JEEWON, R; HYDE, KD. 2011. Nematode-trapping fungi. Current Research in Environmental & Applied Mycology 1: 1-26.
TIDKE, G; RAI, M. 2006. Biotechnological potential of mushrooms: drugs and dye production. International Journal of Medicinal Mushrooms 8: 351-360.
TRANIER, MS; GROS, JP; QUEIROZ, RC; GONZÁLEZ, CNA; MATEILLE, T; ROUSSOS, S. 2014. Commercial biopesticides against plant parasitic nematodes. Brazilian Archives of Biology and Technology 57: 831-841.
WILCKEN, SRS; GARCIA, MJM; SILVA, N. 2004. Reprodução de Meloidogyne incognita raça 2 em diferentes cultivares de alface (Lactuca sativa L.). Arquivos do Instituto Biológico 71: 379-381.
ZECH, WM. 1971. A rating scheme for field evaluation of root- knot nematode infestations. Pflanzenschutz Nachrichten 24: 141-144.

Publication Dates

Publication in this collection
15 Apr 2019
Date of issue
Jan-Mar 2019

History

Received
19 Dec 2017
Accepted
14 Aug 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ABBASI, N.; MOHAMMADI TORKASHVAN, A.; RAHANANDEH, H. 2014. Evaluation of mushroom compost for the bio control root-knot nematode. International Journal of Biociences 5: 147-153.

[2] ABCSEM - Associação Brasileira do Comércio de Sementes e Mudas. October 5, 2016. O mercado de folhosas, números e tendências, divulgação do projeto para o levantamento dos dados socioeconômicos da cadeia produtiva de hortaliças no Brasil. Available at http://www.abcsem.com.br/upload/arquivos/O_mercado_de_folhosas__Numeros_e_Tendencias_-_Steven.pdf
» http://www.abcsem.com.br/upload/arquivos/O_mercado_de_folhosas__Numeros_e_Tendencias_-_Steven.pdf

[3] AGROFIT: Sistema de Agrotóxicos Fitossanitários. August 23, 2017. Ministério da Agricultura, Pecuária e Abastecimento - Coordenação-Geral de Agrotóxicos e Afins/DFIA/DAS. Available at http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons
» http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons

[4] AWD-ALLAH, SF; EL-SHERBINY, AA. 2015. Non chemical control of Heterodera goldeni and Meloidogyne incognita on rice plants using residues of oyster mushroom cultivation and supernatant of Bacillus thuringiensis before transplanting under field microplots conditions. Egypt Journal of agronematology 14: 62-77.

[5] BERNARDI, E. 2007. Cultivo de Pleurotus em substrato capim elefante (Pennisetum purpureum Shum) pasteurizado. Pelotas: UFPEL-FAEM. 81p. (M.Sc. tesis).

[6] CANTERI, MG; ALTHAUS, RA; VIRGENS FILHO, JS; GIGLIOTI, EA; GODOY, CV. 2001. SASM-AGRI - sistema para análise e separação de médias em experimentos agrícolas pelos métodos Scott-Knott, Tukey e Duncan. Revista Brasileira de Agrocomputação 2: 18-24.

[7] CARNEIRO, RMD; ALMEIDA, MRA. 2001. Técnica de eletroforese usada no estudo de enzimas dos nematoides de galhas para identificação de espécie. Nematologia Brasileira 25: 35-44.

[8] CHEN, SY; DICKSON, DW; MITCHELL, DJ. 2000. Viability of Heterodera glycines exposed to fungal filtrates. Journal of Nematology 32: 190-197.

[9] CHRISTIE, JR; PERRY, VG. 1951. Removing nematodes from soil. Proceedings of Helminthological Society of Washington 18: 106-108.

[10] DEGENKOLB, T; VILCINSKAS, A. 2016a. Metabolites from nematophagous fungi and nematicidal natural products from fungi as an alternative for biological control. Part I: metabolites from nematophagous ascomycetes. Applied Microbiololy and Biotechnololy 100: 3799-3812.

[11] DEGENKOLB, T; VILCINSKAS, A. 2016b. Metabolites from nematophagous fungi and nematicidal natural products from fungi as alternatives for biological control. Part II: metabolites from nematophagous basidiomycetes and non-nematophagous fungi. Applied Microbiology and Biotechnology 100: 3813-3824.

[12] DIAS, WP; RIBEIRO, NR; LOPES, ION; GARCIA, A; CARNEIRO, GES; SILVA, JFV. 2007. Manejo de nematoides na cultura da soja. In: CONGRESSO BRASILEIRO DE NEMATOLOGIA, 27. Goiânia. Anais... Goiânia. p.26-30.

[13] EL-SHERBINY, AA; AWD ALLAH, SFA. 2014. Management of the root-knot nematode, Meloidogyne incognita on tomato plants by pre-planting soil biofumigation harvesting residues of some winter crops and waste residues of oyster mushroom cultivation under field conditions. Egyptian Journal of Agronematology 13: 189-202.

[14] FIORI-TUTIDA, ACG; ESTRADA, KRFS; STANGARLIN, JR; PASCHOLATI, SF. 2007. Extratos de Lentinu laedodes e Agaricus blazei sobre Bipolaris sorokiniana e Puccinia recondita f. sp. tritici, in vitro. Summa Phytopathologica 33: 113-118.

[15] GANESHPURKARARAI, G, JAIN, AP. 2010. Medicinal mushrooms: Towards a new horizon. Pharmacognosy Review 4: 127-135.

[16] GENIER, HLA; SOARES, FEF; QUEIROZ, JH; GOUVEIA, AS; ARAÚJO, JV; BRAGA, FR; PINHEIRO, IR; KASUYA, MCM. 2015. Activity of the fungus Pleurotus ostreatus and of its proteases on Panagrellus sp. larvae. African Journal of Biotechnology 14: 1497-1503.

[17] GOSWAMI, BK; PANDEY, RK; RATHOUR, KS; BHATTACHARYA, C; SINGH, L. 2006. Integrated application of some compatible biocontrol agents along with mustard oil seed cake and furadan on Meloidogyne incognita infecting tomato plants. Journal of Zhejiang University Science B7: 873-875.

[18] HASEEB, A; KUMAR, V. 2006. Management of Meloidogyne incognita - Fusarium solani disease complex in brinjal by biological control agents and organic additives. Annals of Plant Protection Sciences 14: 519-521.

[19] HENZ, GP; SUINAGA, F. 2009. Tipos de alface cultivados no Brasil. Comunicado Técnico 75. Embrapa Hortaliças.

[20] HEYDARI, R; POURJAM, E; GOLTAPEH, EM. 2006. Antagonistic effect of some species of Pleurotus on the root-knot nematode, Meloidogyne javanica in vitro. Plant Pathology Journal 5: 173-177.

[21] HONG, L; LIU, Y; FANG, L; LI, X; TANG, N.; ZHANG, K. 2007.Coprinus comatus damages nematode cuticles mechanically with spiny balls and produces potent toxins to immobilize nematodes. Applied and Environmental Microbiology 73: 3916-3923.

[22] HUSSEY, RS; BARKER, KR. 1973. A comparison of methods of collecting inocula of Meloidogyne spp., including a new technique. Plant Disease Report 57: 1025-1028.

[23] KULKARNI, SM; SANGIT, AD. 2000. Cultivation of Hohenbuehelia atrocaerulea (Fr.) Sing. (Agaricomycetideae): a mushroom with nematicidal potential. International Journal of Medicinal Mushrooms 2: 161-163.

[24] LI, G; ZHANG, K; XU, J; DONG, J; LIU, Y. 2007. Nematicidal substances from fungi. Recent Patents on Biotechnology 3: 12-23.

[25] LIMA, JD; MORAES, WS; SILVA, SHMG; IBRAHIM, FN. 2008. Acúmulo de compostos nitrogenados e atividade da redutase do nitrato em alface produzida sob diferentes sistemas de cultivo. Pesquisa Agropecuária Tropical 38: 180-187.

[26] LUDWIG, J; MOURA, AB; GOMES, CB. 2013. Potencial da microbiolização de sementes de arroz com rizobactérias para o biocontrole do nematoide das galhas. Tropical Plant Pathology 38: 264-268.

[27] MARINO, RH; SILVA, DGC. 2013. Controle do nematoide-das-galhas por Pleurotus ostreatus em alface. Scientia Plena 9: 1-6.

[28] OKORIE, CC; ONONUJU, CC; OKWUJIAKO, IA. 2011.Management of Meloidogyne incognita with Pleurotus ostreatus and P. tuberregium in soybean. International Journal of Agriculture and Biology 13: 401-405.

[29] OOSTENBRINK, M. 1966. Major characteristics of the relation between nematodes and plants. Meded. Landbouwhogeschool. Wageningen 66: 3-46.

[30] PINHEIRO, JB; PEREIRA, RB; CARVALHO, ADF; RODRIGUES, CS; SUINAGA, FA. 2013. Manejo de nematoides na cultura da alface. Circular Técnica. Embrapa Hortaliças, 8p.

[31] PRAKOB, W; HOM, JN; SILAPAPONGPRI, PJS; THANUNCHAI, J; CHAISUK, P. 2009. Biological control of lettuce root-knot disease by the used of Pseudomonas aeruginosa, Bacillus subtilis and Paecilomyces lilacinus. Journal of Agricultural Technology 5: 179-191.

[32] PUTZKE, MTL; MATSUMURA, ATS; CAVALCANTI, MAQ; C-FILHO, A. 2007. Taxonomia e importância das espécies de Hohenbuehelia resupinatus e Pleurotus no controle de Meloidogyne javanica. Caderno de Pesquisa série Biologia Universidade de Santa Cruz do Sul 19: 38-81.

[33] RAMOS, C; SAPATA, M; FERREIRA, A; ANDRADA, L; CANDEIAS, M. 2011. Produção de três espécies de cogumelos Pleurotus e avaliação da qualidade em atmosfera modificada. Revista de Ciências Agrárias 34: 57-64.

[34] SANTOS, HS. 1995. Efeitos de sistemas de manejo do solo e de métodos de plantio na produção de alface (Lactuca sativa L.) em abrigo com solo naturalmente infestado com Meloidogyne javanica. Lavras: Universidade Federal de Lavras. 88p. (Ph.D. thesis).

[35] SHARMA, VP. 1994. Potential of Pleurotus sajor-caju for biocontrol of Aphelenchoides camposticola in Agaricus bisporus cultivation. Mushroom Research 3: 15-20.

[36] SWE, A; LI, J; ZHANG, KQ; POINTING, SB; JEEWON, R; HYDE, KD. 2011. Nematode-trapping fungi. Current Research in Environmental & Applied Mycology 1: 1-26.

[37] TIDKE, G; RAI, M. 2006. Biotechnological potential of mushrooms: drugs and dye production. International Journal of Medicinal Mushrooms 8: 351-360.

[38] TRANIER, MS; GROS, JP; QUEIROZ, RC; GONZÁLEZ, CNA; MATEILLE, T; ROUSSOS, S. 2014. Commercial biopesticides against plant parasitic nematodes. Brazilian Archives of Biology and Technology 57: 831-841.

[39] WILCKEN, SRS; GARCIA, MJM; SILVA, N. 2004. Reprodução de Meloidogyne incognita raça 2 em diferentes cultivares de alface (Lactuca sativa L.). Arquivos do Instituto Biológico 71: 379-381.

[40] ZECH, WM. 1971. A rating scheme for field evaluation of root- knot nematode infestations. Pflanzenschutz Nachrichten 24: 141-144.

Treatment	Mortality¹	Hatching	Hatching inhibition
Pleurotus ostreatus	100.00a	1.96b**	98.40b
Boletus sp.	98.96a	4.98b	95.02b
Pleurotus pulmonarius	98.00a	4.59b	95.41b
Pleurotus citrinopileatus	97.88a	3.09b	96.91b
Amanita muscaria	96.58b	2.95b	97.05b
Russula amethystina	95.69b	5.85b	94.15b
Lactarius deliciosus	95.39b	7.12b	92.88b
Suillus sp.	94.36b	3.00b	97.00b
Pleurotus sajor-caju	94.22b	4.04b	95.96b
Pleurotus ostreatoroseus	90.66b	5.62b	94.38b
Control (distilled water)	4.95c	54.66a	45.34a
CV (%)	8.82	35.51	25.30

Treatment	Damages	Number of eggs¹	FR²	Control⁴ (%)
Control³	5.0 a	155000 a	31.00 a	-
Boletus sp.	3.0 c	83444 b	16.68 b	46.20
P. pulmonarius	2.5 c	58778 b	11.75 b	62.09
P. citrinopiliatus	4.5 ab	51556 b	10.31 b	66.74
P. ostreatus	4.0 abc	39996 b	7.99 b	74.22
CV (%)	33.70	73.6	73.6

Treatment	MFPA¹ (g)	MFR²(g)
Boletus sp.	74.06 a	22.95 a
P. pulmonarius	67.11 a	17.78 a
P. citrinopiliatus	66.17 a	18.00 a
P. ostreatus	62.88 a	23.10 a
Non-infested control	64.14 a	12.79 a
Infested control	39.53 b	16.22 a
CV (%)	20.97	50.37

Brasil

Brasil

Potential of aqueous extracts of basidiomycetes to control root-knot nematodes on lettuce

Potencial de extratos aquosos de basidiomicetos no controle de nematoides das galhas em alface

ABSTRACT

RESUMO

MATERIAL AND METHODS

Obtaining aqueous extracts

Inoculum of M. incognita

In vitro tests

Effect of fungi extracts on control of M. incognita in lettuce crop

RESULTS AND DISCUSSION

ACKNOWLEGMENTS

REFERENCES

Publication Dates

History