School of Environment, Harbin Institute of Technology, Harbin 150090, China; Key Laboratory of Marine Genetic Resources, Third Institute of Oceanography, Ministry of Natural Resources of China; Fujian Key Laboratory of Marine Genetic Resources, Xiamen 361005, China.
The Laboratory of Food Engineering and Nutrition, Yellow Sea Fisheries Research Institute, Qingdao 266072, China.
J Hazard Mater. 2024 Mar 5;465:133339. doi: 10.1016/j.jhazmat.2023.133339. Epub 2023 Dec 22.
Plastic waste released into the environments breaks down into microplastics due to weathering, ultraviolet (UV) radiation, mechanical abrasion, and animal grazing. However, little is known about the plastic fragmentation mediated by microbial degradation. Marine plastic-degrading bacteria may have a double-edged effect in removing plastics. In this study, two ubiquitous marine bacteria, Alcanivorax xenomutans and Halomonas titanicae, were confirmed to degrade polystyrene (PS) and lead to microplastic and nanoplastic generation. Biodegradation occurred during bacterial growth with PS as the sole energy source, and the formation of carboxyl and carboxylic acid groups, decreased heat resistance, generation of PS metabolic intermediates in cultures, and plastic weight loss were observed. The generation of microplastics was dynamic alongside PS biodegradation. The size of the released microplastics gradually changed from microsized plastics on the first day (1344 nm and 1480 nm, respectively) to nanoplastics on the 30th day (614 nm and 496 nm, respectively) by the two tested strains. The peak release from PS films reached 6.29 × 10 particles/L and 7.64 × 10 particles/L from degradation by A. xenomutans (Day 10) and H. titanicae (Day 5), respectively. Quantification revealed that 1.3% and 1.9% of PS was retained in the form of micro- and nanoplastics, while 4.5% and 1.9% were mineralized by A. xenomutans and H. titanicae at the end of incubation, respectively. This highlights the negative effects of microbial degradation, which results in the continuous release of numerous microplastics, especially nanoplastics, as a notable secondary pollution into marine ecosystems. Their fates in the vast aquatic system and their impact on marine lives are noted for further study.
塑料废弃物在环境中由于风化、紫外线(UV)辐射、机械磨损和动物啃食而分解为微塑料。然而,微生物降解介导的塑料碎裂过程知之甚少。海洋塑料降解细菌在去除塑料方面可能具有双重作用。在这项研究中,两种普遍存在的海洋细菌——Alcanivorax xenomutans 和 Halomonas titanicae,被证实能够降解聚苯乙烯(PS)并导致微塑料和纳米塑料的产生。在以 PS 为唯一能源的细菌生长过程中发生了生物降解,并且观察到羧基和羧酸基团的形成、耐热性降低、培养物中 PS 代谢中间产物的产生以及塑料重量损失。微塑料的生成与 PS 的生物降解是动态的。随着 PS 的生物降解,释放的微塑料的尺寸逐渐从第一天的微塑料(分别为 1344nm 和 1480nm)变为第 30 天的纳米塑料(分别为 614nm 和 496nm)。由这两种测试菌株从 PS 薄膜中释放的峰值分别达到 6.29×10 个/L 和 7.64×10 个/L(来自 A. xenomutans 的降解,第 10 天;来自 H. titanicae 的降解,第 5 天)。定量结果表明,A. xenomutans 和 H. titanicae 在培养结束时,分别以微塑料和纳米塑料的形式保留了 1.3%和 1.9%的 PS,而 4.5%和 1.9%的 PS 被矿化。这突出了微生物降解的负面影响,导致大量微塑料,尤其是纳米塑料的持续释放,成为海洋生态系统中显著的二次污染。它们在广阔水生系统中的命运及其对海洋生物的影响值得进一步研究。
