Y Matsumiya1, N Murata, E Tanabe, K Kubota, M Kubo. 1. Department of Bioscience and Technology, College of Life Sciences, Ritsumeikan University, Kusatsu, Shiga, Japan.
Abstract
AIMS: To degrade ether-type polyurethane (ether-PUR), ether-PUR-degrading micro-organism was isolated. Moreover, ether-PUR-degrading mechanisms were analysed using model compounds of ether-PUR. METHODS AND RESULTS: A fungus designated as strain PURDK2, capable of changing the configuration of ether-PUR, has been isolated. This isolated fungus was identified as Alternaria sp. Using a scanning electron microscope, the grid structure of ether-PUR was shown to be melted and disrupted by the fungus. The degradation of ether-PUR by the fungus was analysed, and the ether-PUR was degraded by the fungus by about 27.5%. To analyse the urethane-bond degradation by the fungus, a degraded product of ethylphenylcarbamate was analysed using GC/MS. Aniline and ethanol were detected by degradation with the supernatant, indicating that the fungus secreted urethane-bond-degrading enzyme(s). PURDK2 also degraded urea bonds when diphenylmethane-4,4'-dibutylurea was used as a substrate. CONCLUSIONS: The enzyme(s) from PURDK2 degraded urethane and urea bonds to convert the high molecular weight structure of ether-PUR to small molecules; and then the fungus seems to use the small molecules as an energy source. SIGNIFICANCE AND IMPACT OF THE STUDY: Ether-PUR-degrading fungus, strain PURDK2, was isolated, and the urethane- and urea-bonds-degrading enzymes from strain PURDK2 could contribute to the material recycling of ether-PUR.
AIMS: To degrade ether-type polyurethane (ether-PUR), ether-PUR-degrading micro-organism was isolated. Moreover, ether-PUR-degrading mechanisms were analysed using model compounds of ether-PUR. METHODS AND RESULTS: A fungus designated as strain PURDK2, capable of changing the configuration of ether-PUR, has been isolated. This isolated fungus was identified as Alternaria sp. Using a scanning electron microscope, the grid structure of ether-PUR was shown to be melted and disrupted by the fungus. The degradation of ether-PUR by the fungus was analysed, and the ether-PUR was degraded by the fungus by about 27.5%. To analyse the urethane-bond degradation by the fungus, a degraded product of ethylphenylcarbamate was analysed using GC/MS. Aniline and ethanol were detected by degradation with the supernatant, indicating that the fungus secreted urethane-bond-degrading enzyme(s). PURDK2 also degraded urea bonds when diphenylmethane-4,4'-dibutylurea was used as a substrate. CONCLUSIONS: The enzyme(s) from PURDK2 degraded urethane and urea bonds to convert the high molecular weight structure of ether-PUR to small molecules; and then the fungus seems to use the small molecules as an energy source. SIGNIFICANCE AND IMPACT OF THE STUDY: Ether-PUR-degrading fungus, strain PURDK2, was isolated, and the urethane- and urea-bonds-degrading enzymes from strain PURDK2 could contribute to the material recycling of ether-PUR.
Authors: Ausana Mapook; Kevin D Hyde; Khadija Hassan; Blondelle Matio Kemkuignou; Adéla Čmoková; Frank Surup; Eric Kuhnert; Pathompong Paomephan; Tian Cheng; Sybren de Hoog; Yinggai Song; Ruvishika S Jayawardena; Abdullah M S Al-Hatmi; Tokameh Mahmoudi; Nadia Ponts; Lena Studt-Reinhold; Florence Richard-Forget; K W Thilini Chethana; Dulanjalee L Harishchandra; Peter E Mortimer; Huili Li; Saisamorm Lumyong; Worawoot Aiduang; Jaturong Kumla; Nakarin Suwannarach; Chitrabhanu S Bhunjun; Feng-Ming Yu; Qi Zhao; Doug Schaefer; Marc Stadler Journal: Fungal Divers Date: 2022-09-15 Impact factor: 24.902
Authors: María José Cárdenas Espinosa; Andrea Colina Blanco; Tabea Schmidgall; Anna Katharina Atanasoff-Kardjalieff; Uwe Kappelmeyer; Dirk Tischler; Dietmar H Pieper; Hermann J Heipieper; Christian Eberlein Journal: Front Microbiol Date: 2020-03-27 Impact factor: 5.640