Metabolic and Genetic Properties of Petriella setifera Precultured on Waste.

Karolina Oszust,Giorgia Pertile,Anna Siczek,Magdalena Frąc,Jacek Panek,Marta Oleszek

doi:10.3389/fmicb.2018.00115

Karolina Oszust, Giorgia Pertile + Show 4 more

Open Access

https://doi.org/10.3389/fmicb.2018.00115

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Abstract

Although fungi that belong to Petriella genus are considered to be favorable agents in the process of microbial decomposition or as plant endophytes, they may simultaneously become plant pests. Hence, nutrition factors are supposed to play an important role. Therefore, it was hypothesized that Petriella setifera compost isolates, precultured on three different waste-based media containing oak sawdust, beet pulp (BP) and wheat bran (WB) will subsequently reveal different metabolic properties and shifts in genetic fingerprinting. In fact, the aim was to measure the influence of selected waste on the properties of P. setifera. The metabolic potential was evaluated by the ability of five P. setifera strains to decompose oak sawdust, BP and WB following the MT2 plate® method and the catabolic abilities of the fungus to utilize the carbon compounds located on filamentous fungi (FF) plates®. Genetic diversity was evaluated using Amplified Fragment Length Polymorphism analysis performed both on DNA sequences and on transcript-derived fragments. P. setifera isolates were found to be more suitable for decomposing waste materials rich in protein, N, P, K and easily accessible sugars (as found in WB and BP), than those rich in lignocellulose (oak sawdust). Surprisingly, among the different waste media, lignocellulose-rich sawdust-based culture chiefly triggered changes in the metabolic and genetic features of P. setifera. Most particularly, it contributed to improvements in the ability of the fungus to utilize waste-substrates in MT2 plate® and two times increase the ability to catabolize carbon compounds located in FF plates®. Expressive metabolic properties resulting from being grown in sawdust-based substrate were in accordance with differing genotype profiles but not transcriptome. Intraspecific differences among P. setifera isolates are described.

Highlights

Fungi represent a large share of the total biodiversity on Earth and they are regarded as key players in performing numerous ecosystem functions, especially in soil
All wastes were represented by similar total solids (TS), volatile solids (VS), and crude ash (CA) content
wheat bran (WB) encompassed the highest content of crude fat (CF) (3.77% TS), crude protein (CP) (17.94% TS), and non-fiber carbohydrates (NFC) (28.63% TS), compared with oak sawdust and beet pulp (BP)

Summary

Introduction

Fungi represent a large share of the total biodiversity on Earth and they are regarded as key players in performing numerous ecosystem functions, especially in soil. It is widely acknowledged that organic waste, applied as biofertilizers or exogenous organic matter (EOM) is superior to chemical fertilizers at Petriella setifera Diversity improving the biological quality of soil (Li R. et al, 2017). A wide range of biofertilizers have been proposed over the last couple of decades. These were, for example, mainly manure (Chen and Jiang, 2014), composts or biochar (Liu et al, 2012), waste from biogas plants (Minale and Worku, 2014), municipal sewage sludge (Tontti et al, 2017), dairy sewage sludge (Frac et al, 2012), algae or zeolite (Türkmen and Kütük, 2017), bone meal (Chen et al, 2011), agricultural or food wastes (Zhang et al, 2011). Land application is the best recycling option since most organic wastes contain valuable nutrients and organic matter which may be used to improve soil fertility

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