Field evaluation of single and interaction effects of nematode, fungus and bacterium on nodulation and pathological parameters of Bambara groundnut (Vigna subterrenea (l.) Verdc.) in field condition

Ngbada Nkwam Agbor ,Iheukwumere Charles Chidozie ,Aguoru Celestine Uzoma ,Olalekan Joseph Olasan ,Okoh Thomas ,Onen Ibang

doi:10.24294/th.v6i2.3203

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Field evaluation of single and interaction effects of nematode, fungus and bacterium on nodulation and pathological parameters of Bambara groundnut (Vigna subterrenea (l.) Verdc.) in field condition

Ngbada Nkwam Agbor

Iheukwumere Charles Chidozie

Aguoru Celestine Uzoma

Olalekan Joseph Olasan

Okoh Thomas

Onen Ibang

Trends in Horticulture 2023, 6(2); https://doi.org/10.24294/th.v6i2.3203

Submitted：07 Nov 2023

Accepted：28 Nov 2023

Published：15 Dec 2023

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Abstract

The aim of the present study was to determine the effects of single and mixed infections of nematode (Meloidogyne javanica), fungus (Fusarium oxysporum) and bacterium (Xanthomonas axonopodis) on nodulation and pathological parameters of Bambara groundnut (Vigna subterrenea (L.) Verdc.) in field condition. Nematode infested field was used while other pathogens were obtained from diseased plants. The Randomized Complete Block Design (RCBD) was adopted in a 5 × 9 × 5 factorial design (5 blocks, 9 treatments and 5 replicates per treatments) resulting in 225 experimental units. In each experimental unit, three seeds were sown to a depth of 5cm and thinned to one plant per planting hole after germination at day 7. Treatments were inoculated into test plant following standard methods. As a result, the control treatment recorded the highest number of nodules (64.0 ± 6.91), followed by bacterium (45.2 ± 5.11) while N + F + B had the lowest number of root nodules (23.4 ± 2.42). Simultaneous treatment (N + F + B) gave the highest percentage reduction in nodulation (63.44%), followed by treatment N + F7 (56.25%). Fungus treatment recorded the highest mean wilted plants (3.8 + 0.20) followed by N + F7 treatment (3.40 + 0.40). Gall formation in the nematode treatment increased proportionately by 56.33% as the highest recorded, followed by treatment N + F7 with 50.0%. Treatment N + F7 had the highest reproduction factor (Rf) value of 9.30 followed by nematode (8.30), N + B7 (7.40), N + F + B (6.80) and N + F14 (6.50). Zero (0) Rf value was recorded in fungus, bacterium and control treatments. The observed differences in nodulation and pathological parameters among the treatments are significant (P < 0.05). The data provided in this work is important in the control of the three pathogens affecting the productivity of Bambara nut. Formulation of a single protectant should be designed to have potent effects on the three pathogens to achieve effective protection and good production of Bambara nut.

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References

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