Assessment of Nematicidal and Plant Growth-promoting Effects of Sp. JB-2 in Root-knot Nematode-infested Soil

Overview

Journal Front Plant Sci

Date 2023 Aug 4

PMID 37538060

Authors

Jong-Hoon Kim

Byeong-Min Lee

Min-Kyoung Kang

Dong-Jin Park

In-Soo Choi

Ho-Yong Park

Chi-Hwan Lim

Kwang-Hee Son

Affiliations

Soon will be listed here.

Abstract

Root-knot nematodes (RKN), spp., are plant-parasitic nematodes that are responsible for considerable economic losses worldwide, because of the damage they cause to numerous plant species and the inadequate biological agents available to combat them. Therefore, developing novel and eco-friendly nematicides is necessary. In the present study, sp. JB-2, isolated from RKN-infested rhizosphere soil in South Korea, was evaluated to determine its nematicidal and plant growth-promoting effects under and conditions. Cell-free filtrates of the JB-2 strain showed high levels of nematicidal activity against second-stage juveniles (J2) of . , with 87.5% mortality following two days of treatment. In addition, the assessment of the activity against other six plant parasitic nematodes (. , . , . , , , and ) showed that the cell-free filtrates have a broad nematicidal spectrum. The three defense-responsive (-, -, and -) genes were activated, while -- was downregulated when treated with cell-free filtrates of JB-2 cultures on J2. The greenhouse experiments suggested that the cell-free filtrates of the JB-2 strain efficiently controlled the nematode population in soil and egg mass formations of . in tomato ( L., cv. Rutgers). An improvement in the host plant growth was observed, in which the shoot length and fresh weights of shoots and roots increased. The treatment with 10% of JB-2 cell-free filtrates significantly upregulated the expression levels of plant defenses (, , and ) and growth-promoting (, , and ) genes compared with the corresponding parameters of the control group. Therefore, JB-2 could be a promising candidate for the sustainable management of RKN.

Citing Articles

Primes a Multilayered Transcriptional Defense Response to the Nematode spp. in Tomato.

Gonzalez-Cardona C, Lopez W, Jovel J, Soto-Suarez M, Ceballos-Aguirre N Int J Mol Sci. 2024; 25(23).

PMID: 39684296 PMC: 11641443. DOI: 10.3390/ijms252312584.

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