Modern biotechnology in optimizing plant waste utilization

Bohdana Ivanytska,Dejiang Liu,Jan Slaski,Lijuan Tian,Myron Pyzyk,Nataliia Pavliuchenko,Nataliia Zaimenko,Olexandr Slyusarenko,Tianlin Miao

doi:10.46341/pi2020020

Bohdana Ivanytska, Dejiang Liu + Show 7 more

Open Access

https://doi.org/10.46341/pi2020020

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Abstract

The study aimed to develop a modern, cheap, and environmentally safe technology for the disposal of plant waste, with the participation of the most active microorganisms-destructors.The microorganisms’ ability to help transform plant waste into viable, fertile soil was extensively studied. We selected strains of micromycetes Penicillium roseopurpureum, Trichoderma hamatum, T. koningii, Alternaria alternata, and bacteria of the genus Cytophaga, which are characterized by high growth rate and the absence of phytotoxicity. To accelerate microorganism development, we used silicon-containing mineral analcime, which contained immobilized spores of micromycetes and bacterial cells’ suspensions. Modified analcime was added to the waste in a ratio of 10 : 1. The plant remains prepared in this method were analyzed under conditions of both model and vegetation experiments.An evidence for the expediency of using the silicon-containing mineral analcime as a starting substrate for immobilization of spores and suspension of bacterial cells in the culture fluid was provided. The microorganisms involved in the experiment showed a positive result in transforming plant waste during the 30-day observation period. The highest destructive activity against apple and grape waste is characteristic for the T. hamatum strain, for beet waste – P. roseopurpureum. The species-specificity of these destructive microorganisms on plant growth processes was proved. The maximum growth of corn sprouts in apple waste was detected by inoculation with T. koningii spores, grape waste – T. hamatum, and beet waste – a mixture of micromycetes with a Cytophaga sp. suspension. The optimal duration of plant waste transformation using analcime, inoculated with microorganisms, is 20–30 days. In the indoor farming conditions, the standard for utilizing the modified vegetable waste placement was 10 % of the total volume of a substrate during the preparation of soil mixes.The environmental safety of plant waste after their destruction was confirmed. The presence of a silicon-containing mineral in the mixture leads to increased growth and plant development, optimization of the agrophysical, agrochemical, and biological parameters of the soil, reducing soil fatigue, and increasing fertility.

Highlights

One of the most pressing issues of today, on which humanity’s future depends, involves major environmental challenges
Previous studies have shown that the P. roseopurpureum strain secretes secondary metabolites during growth, curvularine (Gavrilov et al, 2013), which is toxic to phytopathogens of the genera Fusarium, Aureobasidium, Botrytis, and others
The absence of any inhibition of the development of T. hamatum and T. koningii strains in cocultivation with P. roseopurpureum is shown on the Fig. 1

Summary

Introduction

One of the most pressing issues of today, on which humanity’s future depends, involves major environmental challenges. Crop production, processing, and consumption of its products lead to vast amounts of consumed biomass. Using this organic waste to increase the balance of organic matter in the soil is usually the most acceptable solution, but not in all cases. This is since the direct application of waste enhances the greenhouse effect (Powlson et al, 2008) and often leads to increased soil toxicity, which is caused by both chemical and biological properties of plant material and pesticide residues (Naseer et al, 2014). Research regarding the study of microorganisms’ taxonomic specificity that colonize plant raw materials during its processing has become especially relevant

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