Abstract

Gliotoxin produced by Trichoderma virens is inhibitory against various phytopathogenic fungi and bacteria. However, its stability in soil-ecosystem has not yet been well-defined. This study aimed to decipher its persistence and behaviour in growth media, irrigation water and soil ecosystems. Gliotoxin production was noticed at logarithmic growth phase and converted into bis-thiomethyl gliotoxin at late stationary growth phase of T. virens in acidic growth medium. But, no gliotoxin production was observed in neutral and alkaline growth medium. Gliotoxin was stable for several days in acidic water but degraded in alkaline water. Degradation of gliotoxin was more in unsterile soil than sterile soil and also that was higher under wet soil than dry soil. Degradation of gliotoxin was hastened by alkaline pH in wet soil but not in dry soil. Under unsterile soil conditions, high soil moisture increased the degradation of gliotoxin and the degradation of gliotoxin occurred quickly in alkaline soil (in 5 days) compared to acidic soil (in 10 days). Under sterile soil conditions, high soil moisture also enhanced the degradation of gliotoxin but level of degradation was less compared to unsterile conditions. Thus, gliotoxin stability is influenced mainly by the soil wetness, soil microbial community and pH conditions.

Highlights

  • Gliotoxin produced by Trichoderma virens is inhibitory against various phytopathogenic fungi and bacteria

  • T. virens strain TK1 produced the highest amount of gliotoxin as that of T. virens strain microbial type culture collection (MTCC) 2977, gliotoxin producing strain used as reference strain

  • Gliotoxin production started from the second day after inoculation of T. virens and its accumulation was maximum on the sixth day of incubation in Weindling medium and there after its accumulation declined sharply

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Summary

Introduction

Gliotoxin produced by Trichoderma virens is inhibitory against various phytopathogenic fungi and bacteria. Degradation of gliotoxin was hastened by alkaline pH in wet soil but not in dry soil. High soil moisture enhanced the degradation of gliotoxin but level of degradation was less compared to unsterile conditions. Mutant strains of T. virens lacking gliotoxin production were less effective for the control of damping off disease caused by Pythium spp. and R. solani in cotton and zinnia plants compared to its isogenic wild-type ­strain[16,17]. In addition to crop protection, T. virens enhances the plant growth and yield potential by producing plant growth promoting substances such as indole acetic a­ cids[18,19,20,21] It is called as plant growth promoting fungus

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