ABSTRACT

Tropical and subtropical fruit production plays an important role in the country’s economic scenario and has been affected by root-knot nematode. The jaboticaba tree is a plant widely cultivated in Brazil, and among the problems of the crop is the root-knot nematode of the genus Meloidogyne. This study aimed to evaluate the hostability of jaboticaba tree cv. ‘Sabará’, in different inoculum concentrations of Meloidogyne incognita and Meloidogyne javanica. The inoculum used in the experiment was obtained from the roots of tomato cv. ‘Santa Cruz’. Jaboticaba trees were subjected to inoculation with concentrations of 0, 2000, 4000, and 8000 eggs + juvenile plant-1, for both species of nematodes. The plants of jaboticaba cv. ‘Sabará’ showed resistance concerning the development of M. incognita and M. javanica root-knot nematode with Reproduction Factor (RF) <1.

Keywords
Meloidogyne incognita ; Meloidogyne javanica ; Myrtaceae

RESUMO

A fruticultura tropical e subtropical tem um papel relevante no cenário econômico do país, e vem sendo prejudicada pelo nematoide das galhas. A jabuticabeira é uma planta bastante cultivada no Brasil e entre os problemas da cultura, estão os nematoides do gênero Meloidogyne. Este trabalho objetivou avaliar a hospedabilidade da jabuticabeira cv. Sabará, em diferentes concentrações de inóculos de Meloidogyne incognita e Meloidogyne javanica. Os inóculos utilizados no experimento foram obtidos a partir de raízes de tomateiro cv. Santa Cruz. As jabuticabeiras foram submetidas à inoculação com as concentrações de 2000, 4000 e 8000 ovos + juvenis planta-1, para ambas as espécies dos nematoides. As plantas de jabuticaba cv. Sabará demonstraram resistência em relação ao desenvolvimento dos nematoides de galhas M. incognita e M. javanica com Fator de Reprodução (FR) <1.

Palavras-chave
Meloidogyne incognita ; Meloidogyne javanica ; Myrtaceae

The jaboticaba tree, Myrciaria jaboticaba (Vell.) Berg, is a native species from Brazil, belonging to the Myrtaceae family, and the cultivar ‘Sabará’ is the most cultivated in the country (⁵5 Lorenzi, H.; Bacher, L.B.; Lacerda, M.T.C.; Sartori, S.F. Frutas brasileiras e exóticas cultivadas: de consumo in natura. Instituto Plantarum de Estudos da Flora, São Paulo, p.672, 2006.), found most frequently in the states of Goiás, Minas Gerais, and São Paulo (⁴4 Danner, M.A.; Citadin, I.; Sasso, S.A.Z.; Sachet, M.R.; Malagi, G. Modo de reprodução e viabilidade de pólen de três espécies de jabuticabeira. Revista Brasileira de Fruticultura, Jaboticabal, v.33, n.2, p.345-352, 2011.). Fruits are highly appreciated, and the economic potential of this species covers the fresh or industrialized fruit market (⁹9 Rufino, M.S.M. Propriedades funcionais de frutas tropicais brasileiras não tradicionais. 2008. 263f. Tese (Doutorado em Agronomia: Fitotecnia) Faculdade de Agronomia, Universidade Federal Rural do Semiárido, Mossoró.).

Nematodes are important factors limiting the cultivation of several agricultural species, including fruit species. The root-knot nematode (Meloidogyne sp.) is the most common genus, causing severe losses in agricultural production (⁶6 Nyczepir, A.P. Nematode management strategies in stone fruits in the United States. Journal of Nematology, Lakeland, v.23, n.3, p.334-341, 1991.), however, little is known about the effects of these nematodes’ parasitism on the jaboticaba tree. Therefore, the study aimed to evaluate the tolerance of jaboticaba tree cv. ‘Sabará’, under increasing concentrations of the root-knot nematode inoculum, Meloidogyne incognita (Kofoid & White) and Meloidogyne javanica (Treub) Chitwood.

A completely randomized design (CRD) in a 4x2 factorial scheme (concentrations of inoculum x nematodes) was used in the research. The experimental plot was represented by one plant per pot, and each concentration consisted of eight replications, totaling 56 jaboticaba seedlings, cultivar ‘Sabará’. As a susceptibility pattern (positive control), eight tomato plants, cultivar ‘Santa Cruz Kada’, were used. The nematode inoculum used was obtained from the tomato roots of the cultivar ‘Santa Cruz Kada, processed by the technique proposed by Coolen; D’Herde (³3 Coolen, W.A.; D’Herde, C.J. A method for the quantitative extraction of nematodes from plant tissue. Ghent: Nematology and Entomology Research Station, 1972. 77p.). The nematode species were previously identified using morphological characters from the female perineal region and by confirming the Meloidogyne species, using the isoenzyme electrophoresis technique (²2 Carneiro, R.M.D.; Almeida, M.R.A. Técnica de eletroforese usada no estudo de enzimas dos nematoides de galhas para identificação de espécie. Nematologia Brasileira, Piracicaba, v.25, n.1, p.35-44. 2001.).

The certified jaboticaba seedlings of cultivar ‘Sabará’ were purchased from a commercial nursery. To produce tomato seedlings (positive control), sowing was carried out in polyethylene trays, the commercial substrate was used. The eight-month-old jaboticaba seedlings and the tomato seedlings after 21 days after sowing were transplanted into polypropylene pots (2 L), containing soil previously autoclaved at 120 ºC for 20 minutes, in the proportion of 1:1 (soil:sand). Inoculations were performed one week after transplantation, pouring 5 mL of each nematode suspension into three holes made in the substrate, 2 cm from the plants.

The concentrations used in each suspension were: 0 (control), 2,000, 4,000, and 8,000 eggs + juveniles of the second stage (J2) of M. incognita and M. javanica per jaboticaba seedling. The inoculation of the nematode suspension in tomato was with a concentration of 3,000 eggs + juveniles of the second stage (J2) of M. incognita and M. javanica. The positive control (tomato seedlings) was used only to verify the viability of the inoculum. Hostability assessment was carried out 90 days after inoculation (DAI) of the plants. The root system of each plant was carefully washed under running water, then weighed on an analytical balance and processed according to the methodology described above. The reproduction factor was calculated using the equation RF = Fp/Ip, where: RF - reproduction factor, Fp - final population density, and Ip - initial population density (⁷7 Oostenbrink, M. Major characteristics of the relation between nematodes and plants. Mededelingen Landbouw, Suriname, v.66, n.4, p.1-46, 1966.).

After 90 days of inoculation of jaboticaba trees and tomato, it was possible to observe the presence of nematodes in the root system of plants inoculated with M. incognita. The final population density (eggs + juveniles) in 10 g of roots of jaboticaba seedlings showed a maximum increase of up to 4350 eggs + juvenile in 5 mL (Figure 1) according to the increasing dose of M. incognita inoculum. From this period, there was a marked decrease in the population density of nematodes due to the deficiency of food at the feeding site, leading to less population growth.

Figura 1
Relationship of the final population density (FP) of the nematode Meloidogyne incognita and Meloidogyne javanica in jabot.icaba seedlings under different concentrations of inoculum

As for the species M. javanica, there was a maximum increase in the population with the dosage of 7070 eggs + juvenile/5 mL. From that level, the population decrease verified in 10 g of roots started (Figure 1). The reaction of the jaboticaba seedlings to the species M. incognita and M. javanica proved to be tolerance, according to the criterion of Oostenbrink (⁷7 Oostenbrink, M. Major characteristics of the relation between nematodes and plants. Mededelingen Landbouw, Suriname, v.66, n.4, p.1-46, 1966.), in all inoculation levels that were submitted, as they presented RF <1.0. In this case, the plants presented the nematodes internally in their roots; however, there was a reduction in their multiplication, being the jaboticaba tree cv. ‘Sabará’, considered a plant resistant to these phytonematodes.

Although M. javanica has a low population density when compared to M. incognita, under the same inoculated concentrations, the correlation coefficient showed an r = 0.99, evidencing that there was a correlation close to 1, and the variation coefficient (CV) of 30.29%. The formation of galls outside the plant roots was not observed in the root samples of the jaboticaba trees, probably due to root lignification, which may have hindered the formation of galls during the evaluation period of the experiment (90 days after inoculation).

The lowest multiplication rate among all tested levels was at the dosage of 8000 eggs + juvenile /5 mL of M. incognita, with an RF = 0.01 (Table 1). Regarding the root fresh mass, there was no statistical difference between the treatments evaluated for both species of nematodes. However, when compared with the controls, lower values for root mass were found for both phytonematodes. In the literature, there are several fruit trees of subtropical and temperate climate that showed resistance reaction to M. incognita and M. javanica (¹1 Carneiro, R.M.D.G.; Cirotto, P.A.; Quintanilha, A.P.; Silva, D.B.; Carneiro, R.G. Resistance to Meloidogyne enterolobii in Psidium spp. accessions and their grafting compatibility with P. guajava cv. Paluma. Fitopatologia Brasileira, Brasília, DF, v.32, n.4, p.281-284, 2007., ⁸8 Rossi, C.E.; Ferraz, L.C.C.B.; Montaldi, P.T. Resistência de frutíferas de clima subtropical e temperado a Meloidogyne incognita raça 2 e M. javanica. Arquivos do Instituto Biológico, São Paulo, v.69, n.2, p.43-49, 2002.).

According to the results obtained in the present study, it can be said that the jaboticaba tree cv. ‘Sabará’ did not offer favorable conditions for the population increase of the studied nematode species, thus presenting tolerance behavior to Meloidogyne incognita and Meloidogyne javanica.

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