<i>Trichoderma</i>‐primed rice straw alters structural and functional properties of sodic soil

Tandon, Ashmita; Anshu, Anshu; Kumar, Sanjeev; Yadav, Udit; Mishra, Shaunak; Srivastava, Suchi; Chauhan, Puneet Singh; Srivastava, Pankaj; Bahadur, Lal; Shirke, Pramod Arvind; Srivastava, Mohit; Tewari, Shri Krishna; Singh, Poonam

doi:10.1002/ldr.4151

Cited by 5 publications

(3 citation statements)

References 43 publications

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“…Numerous studies have indicated that inoculated PSB can markedly improve soil properties (Mahdi et al, 2020; Tahir et al, 2018). To a great extent, microorganisms in inoculants may influence plant development and nutrient uptake (Spohn et al, 2020; Tandon et al, 2022; Wong et al, 2022). In this study, we found that inoculated XQP35 and SQP80 treatments significantly increased maize biomass and the relative chlorophyll content (Figure 2).…”

Section: Discussionmentioning

confidence: 99%

Inoculation with phosphate‐solubilizing bacteria alters microbial community and activates soil phosphorus supply to promote maize growth

Sheng

Zheng

et al. 2022

Land Degrad Dev

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Phosphorus (P) is one of the essential macronutrients for plants, but agricultural soil generally lacks available P. This study aims to ascertain the impact of phosphatesolubilizing bacterial inoculation on the development of maize, soil characteristics, P fractions, and the microbial population in the soil. In this experiment, we explored the P solubilizing ability of P-solubilizing bacteria through liquid culture. In a maize pot experiment, soil P fractions and maize growth were examined, and a metagenomic sequence was constructed to analyze the soil microbial community and gene abundances and to link their relationship. In the shaking flask culture experiment, it was found that the Burkholderia (XQP35) and Raoultella (SQP80) have a strong capability for calcium phosphate and calcium phytate. Compared with the blank control, the XQP35 and SQP80 treatments could improve maize biomass and the soil nutrient status. Moreover, SQP80 treatments increased the soil acid phosphatase activity. SQP80 inoculation dramatically decreased the variety of the soil microbial community and the abundance of Acidobacteria. We found that the different treatments had no significant effect on the number of genes but that the SQP80 treatments significantly increased the P-cycling pathway gene family phoA and phoD compared with the CK treatment. Our results demonstrated that inoculation with XQP35 and SQP80 could dissolve varieties of insoluble P and, together with functional pathways of P-cycling, promote the transformation of P fractions and ultimately increase soil

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Section: Discussionmentioning

confidence: 99%

Inoculation with phosphate‐solubilizing bacteria alters microbial community and activates soil phosphorus supply to promote maize growth

Sheng

Zheng

et al. 2022

Land Degrad Dev

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“…colonization in plants may be due to inhibition of Na + uptake. T. asperellum altered the concentration of Nitrogen, a nutrient directly intricate in the composition of chlorophyll (Lawson & Flexas, 2020;Boamah et al, 2021;Tandon et al, 2022).…”

Section: Antioxidant Enzymes Activitiesmentioning

confidence: 99%

Role of Trichoderma asperellum in mitigating NaCl stress in tomato substantiated by anti-oxidative enzymes

Konappa,

Krishnamurthy,

M. Singh

et al. 2023

MSA

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Salinity is a major abiotic stress that limits the growth and development of plants, and is no special to tomato. Scientists are in constant search for natural remedies against abiotic stress affecting crops worldwide. Beneficial microbes are abundantly available in nature, and if employed rationally, bound to benefit micro-biota of soil. Trichoderma sp. stimulates plant growth and resistance to a varied range of adverse environmental conditions. The present study demonstrates the effect of two Trichoderma asperellum isolates (T4 and T8) in alleviating the deleterious effects of varying concentrations of NaCl (0-200 mM) stress in tomato. Treatment with T. asperellum isolates reduced the effect of stress and tomato seedlings showed significant improvement in seed germination; shoot and root length, shoot and root fresh weight, plant dry weight and chlorophyll content along with decrease in seedling death as compared to control. The T. asperellum treatments in tomato plants under NaCl stress also significantly increased the soluble sugar and protein. The antioxidant enzymes, CAT, POX, SOD and APX in tomato seedlings also significantly increased with T. asperellum treatment, as compared to control. These results prove T. asperellum to be beneficial in imparting NaCl stress tolerance in tomato and a new paradigm for developing environmentally safe alternative for improvement of NaCl stress tolerance.

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“…The colonisation of cucumber roots by T. asperellum has been shown to enhance the availability of phosphorus (P) with a significant enhancement in plant biomass (Yedidia et al, 2001). Moreover, T. harzianum and T. longibrachiatum can improve the solubility of P, iron (Fe), copper (Cu), manganese (Mn), and zinc (Zn) and reduce the fixation of Fe and Cu in soil (Conte et al, 2022;Tandon et al, 2022). It has been shown that Trichoderma spp.…”

Section: Figurementioning

confidence: 99%

Trichoderma affects plant growth and soil ecological environment: A mini-review

Zhu

Zhao

Wang

et al. 2022

Zemdirbyste-Agriculture

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Trichoderma is a genus of widespread filamentous fungi widely used in agriculture as biofungicides for controlling a wide range of plant diseases. Trichoderma, as is well known, can not only effectively control crop diseases but also improve soil physico-chemical properties and increase soil productivity. However, the effects of its control on crop growth and the soil's ecological environment are unclear. The results of Trichoderma on disease resistance, yield, and crop growth as well as the effects of Trichoderma on the soil ecological environment from the standpoint of soil physical, chemical, and microbial properties were therefore reported in this study. Furthermore, this paper highlighted the shortcomings of the existing research on the impact of Trichoderma on crop and soil properties and emphasised opportunities to address the gaps in the existing research on the effects of Trichoderma on crops and soil attributes. This review will provide a theoretical foundation for further research and application of Trichoderma in agricultural production.

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Trichoderma‐primed rice straw alters structural and functional properties of sodic soil

Cited by 5 publications

References 43 publications

Inoculation with phosphate‐solubilizing bacteria alters microbial community and activates soil phosphorus supply to promote maize growth

Inoculation with phosphate‐solubilizing bacteria alters microbial community and activates soil phosphorus supply to promote maize growth

Role of Trichoderma asperellum in mitigating NaCl stress in tomato substantiated by anti-oxidative enzymes

Trichoderma affects plant growth and soil ecological environment: A mini-review

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