Liu Jiawei, Zeng Qingyi, Lei Huirui, Xin Kaiyuan, Xu Anming, Wei Ren, Li Ding, Zhou Jie, Dong Weiliang, Jiang Min
Key Laboratory for Waste Plastics Biocatalytic Degradation and Recycling, College of Biotechnology and Pharmaceutical Engineering, Nanjing Tech University, Nanjing 211800, PR China.
Junior Research Group Plastic Biodegradation, Department of Biotechnology and Enzyme Catalysis, Institute of Biochemistry, University of Greifswald, Greifswald, Germany.
J Hazard Mater. 2023 Apr 15;448:130776. doi: 10.1016/j.jhazmat.2023.130776. Epub 2023 Jan 11.
Microorganisms capable of decomposing polyurethane (PU) and other plastics have the potential to be used in bio-recycling processes. In this study, 20 PU-degrading strains were isolated, including 11 bacteria and 9 fungi, using a synthesized poly(1,4-butylene adipate)-based PU (PBA-PU) as the screening substrate. Three PU substrates with increasing structure complexities were used for a thorough evaluation of microbial degradation capacity: Impranil® DLN-SD, PBA-PU film and PU foam waste. After 4 days, the best fungal PBA-PU degrader, Cladosporium sp. P7, could degrade 94.5% of Impranil® DLN-SD. After 28 days of cultivation, 32.42% and 43.91% of solid PBA-PU film was converted into soluble small molecules when used as the sole carbon source or in a medium with other co-carbon sources, respectively. Accordingly, the weight loss of PU foam waste after 15 days was 15.3% for the sole carbon condition and 83.83% for the co-carbon conditions. Furthermore, PBA-PU was used for metabolic pathway analysis because of its known composition and chemical structure. Six metabolites were identified during the degradation process of PBA-PU, including adipic acid (AA), 1,4-butanediol (BDO), and 4,4'-methylenedianiline (MDA), which can also be used as the sole carbon source to grow the fungal strain P7, resulting in the discovery of two MDA metabolites during the cultivation processes. Based on the presence of these eight metabolites, we hypothesized that PBA-PU is first depolymerized by the fungal strain P7 via ester and urethane bond hydrolysis, followed by intracellular metabolism and mineralization of the three monomers to CO and HO.
能够分解聚氨酯(PU)和其他塑料的微生物具有用于生物回收过程的潜力。在本研究中,以合成的聚(己二酸1,4-丁二醇酯)基PU(PBA-PU)作为筛选底物,分离出20株PU降解菌株,其中包括11株细菌和9株真菌。使用三种结构复杂性递增的PU底物对微生物降解能力进行全面评估:Impranil® DLN-SD、PBA-PU薄膜和PU泡沫废料。4天后,最佳的真菌PBA-PU降解菌枝孢属P7菌株可降解94.5%的Impranil® DLN-SD。培养28天后,当用作唯一碳源或与其他共碳源一起在培养基中使用时,分别有32.42%和43.91%的固体PBA-PU薄膜转化为可溶性小分子。因此,在唯一碳源条件下,15天后PU泡沫废料的重量损失为15.3%,在共碳源条件下为83.83%。此外,由于PBA-PU已知的组成和化学结构,将其用于代谢途径分析。在PBA-PU的降解过程中鉴定出六种代谢物,包括己二酸(AA)、1,4-丁二醇(BDO)和4,4'-亚甲基二苯胺(MDA),它们也可用作真菌菌株P7生长的唯一碳源,在培养过程中发现了两种MDA代谢物。基于这八种代谢物的存在,我们推测PBA-PU首先被真菌菌株P7通过酯键和氨基甲酸酯键水解解聚,随后三种单体在细胞内代谢并矿化为CO和HO。
