Integrated strategies for the control of Nacobbus aberrans s.l. in tomato

SOSA, A.L.; GIRARDI, N.S.; ROSSO, LAURA CRISTINA; PASSONE, M.A.

cordoba

Congreso; 35th Symposium of the European Society of Nematologists; 2024

Microorganisms in the tomato rhizosphere ecosystem develop associations, many of which canbe beneficial or pathogenic for this crop. The plant parasitic nematode (PPN) Nacobbus sp. causesignificant economic losses to horticultural farmers in Argentina. The distribution of this genusis limited to the American continent and is consider a quarantine pest. Biological control strategiesof PPN are environmentally friendly alternatives that ensure the sustainability of the horticulturalsystem. The aim of this study was to evaluate the potential of the combined application of broccoliaqueous extract (BAE) and Purpureocillium lilacinum SR14 fungus in tomato plants (Solanumlycopersicum var. Platense) for the management of N. aberrans s.l. Three-week-old seedlingswere transplanted into pots containing the following treatments: T1: control (sterile horticulturalsoil), T2: naturally infested horticultural soil (NIHS), T3: NIHS + SR14(1x106 spores/g), T4:NIHS + BAE(12%), T5: SHNI + SR14(1x106 spores/g) + BAE(12%). Six replicates per treatmentwere carried out and plants were maintained in a greenhouse. Data, collected at 120 days posttransplant,revealed that tomato growth was affected in NIHS(T2). Plants showed a 47% and 30%reduction in weight and length, respectively, compared to uninfected soil (T1). The highestnumber (4 tomatoes/plant) and weight mean (80 g) of fruits were recorded in T4. The fungusalone or combined with BAE (T3, T4 and T5) effectively controlled N. aberrans s.l. population(reduction percentages: galls = 35, 90 and 93%, egg masses = 5, 94 and 90% and reproductionfactor = 90, 93 and 98%). Physicochemical and biological analyzes were also performed toevaluate the effect of the treatment on the soil ecosystem. The data showed an increase in organicmatter for all treatments compared to the initial condition. Nutrient values such as P, N and Swere maintained throughout the trial. Regarding the soil mycobiota, the fungal count (cfu/g) wasaround 106 for all treatments, but a lower diversity was observed in T5 with a prevalence of P.lilacinum (3x104). As regards the nematofauna, treatments did not significantly influence thenumber of individuals (n°/g of soil) belonging to the different trophic groups (phytopathogens:16, bacteriophages: 19, predators: 10 and fungivores: 15), with the exception of T4, where ahigher count of omnivores was observed (30). Finally, studies on microbial activity revealed thattreatments did not influence the counts (MPN/g) of ammonifying (mean: 1.9x102) anddenitrifying agents (mean: 2.7x1013), while T4 and T5 reduced the density of 1 log unit of nitrate- reducing bacteria (mean: 3.4x106) and aerobic-heterotrophic bacteria (mean: 3.9x108). Inconclusion, the integrated strategy reveal a synergistic effect for the control of N. aberrans s.l.,without affecting tomato plant development, nutrient content and soil microbiome.