Contribution of soil esterase to biodegradation of aliphatic polyester agricultural mulch film in cultivated soils.

Kimiko Yamamoto-Tamura,Yuka Sameshima-Yamashita,Motoo Koitabashi,Tohru Yarimizu,Syuntaro Hiradate,Takashi Watanabe,Hiroko Kitamoto

doi:10.1186/s13568-014-0088-x

Kimiko Yamamoto-Tamura, Yuka Sameshima-Yamashita + Show 5 more

Open Access

https://doi.org/10.1186/s13568-014-0088-x

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Journal: AMB Express	Publication Date: Feb 18, 2015
Citations: 68	License type: CC BY 4.0

Affiliation: National Institute for Agro-Environmental Sciences

Abstract

The relationship between degradation speed of soil-buried biodegradable polyester film in a farmland and the characteristics of the predominant polyester-degrading soil microorganisms and enzymes were investigated to determine the BP-degrading ability of cultivated soils through characterization of the basal microbial activities and their transition in soils during BP film degradation. Degradation of poly(butylene succinate-co-adipate) (PBSA) film was evaluated in soil samples from different cultivated fields in Japan for 4 weeks. Both the degradation speed of the PBSA film and the esterase activity were found to be correlated with the ratio of colonies that produced clear zone on fungal minimum medium-agarose plate with emulsified PBSA to the total number colonies counted. Time-dependent change in viable counts of the PBSA-degrading fungi and esterase activities were monitored in soils where buried films showed the most and the least degree of degradation. During the degradation of PBSA film, the viable counts of the PBSA-degrading fungi and the esterase activities in soils, which adhered to the PBSA film, increased with time. The soil, where the film was degraded the fastest, recorded large PBSA-degrading fungal population and showed high esterase activity compared with the other soil samples throughout the incubation period. Meanwhile, esterase activity and viable counts of PBSA-degrading fungi were found to be stable in soils without PBSA film. These results suggest that the higher the distribution ratio of native PBSA-degrading fungi in the soil, the faster the film degradation is. This could be due to the rapid accumulation of secreted esterases in these soils.

Highlights

Plastics have spread and persisted around the world today because they have been widely used as basic materials in various industries
Incubation period slower than what is desired for practical use, and that hold back farmers from using Biodegradable plastic (BP) mulch films in place of non-degradable ones
We showed the correlations between BP film degradation rate in cultivated soil and esterase activity and ratio of the PBSAdegrading soil fungi in the total soil fungal population

Summary

Introduction

Plastics have spread and persisted around the world today because they have been widely used as basic materials in various industries. Used non-degradable plastic products cause waste management problems. After harvesting, the recovery and recycling of used non-degradable mulch films would require a lot of energy and are labor intensive (Kyrikou and Briassoulis 2007). Biodegradable plastics (BPs) have been developed as a possible solution to such environmental problems caused by the persistent plastic wastes. Mulch films made from BPs are already in the market and are used to help farmers save time and labor as well as to reduce plastic wastes (Ngouajio et al 2008). Physical, and biological degradability of BP mulch films are largely affected by the composition of the BP materials (Kyrikou and Briassoulis 2007).

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