Allamby Q P V, Kidd K A, Prosser R S
Department of Biology, McMaster University, Hamilton, Ontario, Canada.
University of Guelph, School of Environmental Sciences, Guelph, Ontario, Canada.
Environ Toxicol Chem. 2025 Sep 18. doi: 10.1093/etojnl/vgaf234.
In freshwater ecosystems, particularly in riverine sediments, high levels of microplastics (MPs) (<5 mm) have been reported, potentially putting sediment-dwelling macroinvertebrates at risk. However, the effects of MPs on macroinvertebrates remain unclear, despite their critical roles in freshwater food webs. This study investigated whether exposure to three types of MPs (6 µm and 45 µm polystyrene microbeads, 100 µm polyethylene terephthalate (polyester) microfibers) causes adverse effects in the freshwater oligochaete, Tubifex tubifex. Worms were exposed across five environmentally relevant concentrations of each type of MP in sediment (negative control, 0.1, 1, 10, 100, and 1000 MPs per gram dry weight sediment). The exposures were also conducted using either pristine MPs or MPs that had first been colonized with biofilms. Survival of adult worms along with production of cocoons and juvenile worms were assessed following exposure to MPs for 28 days. Changes in the microbiota of whole oligochaetes and sediments were assessed using the V3-V4 regions of the 16S ribosomal RNA gene. Accumulation of MPs was examined after a gut clearance period to assess the ability of the worms to retain MPs. There were no statistically significant effects to survival or reproduction across all exposure concentrations and scenarios for the three types of MPs, along with no evidence of significant MPs accumulation. However, MPs exposure significantly altered host and sediment microbial communities, with effects varying by polymer type, particle size, and condition. In Tubifex tubifex, pristine 45 µm PS microbeads at the highest concentration increased Shannon diversity, while the highest concentration of biofouled 100 µm PET microfibers significantly altered beta diversity. In exposures using biofouled MPs, more differentially abundant bacterial genera were identified compared to pristine MPs, and included taxa linked to nutrient cycling and plastics degradation. In sediments, both alpha and beta diversity were significantly affected by 45 µm PS microbeads, and more differentially abundant bacteria were identified in these exposures compared to 100 µm PET microfibers. While chronic exposure to environmentally realistic MPs did not cause adverse effects to survival or reproduction in Tubifex tubifex, the consequences of alterations to the host microbiome due to MPs exposure requires further investigation.
在淡水生态系统中,尤其是在河流沉积物中,已报道存在高水平的微塑料(MPs,粒径<5毫米),这可能使栖息于沉积物中的大型无脊椎动物面临风险。然而,尽管MPs在淡水食物网中起着关键作用,但其对大型无脊椎动物的影响仍不明确。本研究调查了暴露于三种类型的MPs(6微米和45微米的聚苯乙烯微珠、100微米的聚对苯二甲酸乙二酯(聚酯)微纤维)是否会对淡水寡毛纲动物颤蚓造成不利影响。将颤蚓暴露于沉积物中每种类型MPs的五个与环境相关的浓度下(阴性对照、每克干重沉积物含0.1、1、10、100和1000个MPs)。暴露实验还分别使用原始MPs或预先被生物膜定殖的MPs进行。在暴露于MPs 28天后,评估成年颤蚓的存活率以及茧和幼蚓的产量。使用16S核糖体RNA基因的V3 - V4区域评估整个寡毛纲动物和沉积物的微生物群变化。在肠道清除期后检查MPs的积累情况,以评估颤蚓保留MPs的能力。在所有暴露浓度和三种类型MPs的实验场景下,对存活率或繁殖均无统计学上的显著影响,也没有明显的MPs积累证据。然而,MPs暴露显著改变了宿主和沉积物的微生物群落,其影响因聚合物类型、颗粒大小和条件而异。在颤蚓中,最高浓度的原始45微米聚苯乙烯微珠增加了香农多样性,而最高浓度的生物污染100微米聚酯微纤维显著改变了β多样性。在使用生物污染MPs的暴露实验中,与原始MPs相比,鉴定出更多差异丰富的细菌属,包括与养分循环和塑料降解相关的分类群。在沉积物中,45微米聚苯乙烯微珠显著影响了α多样性和β多样性,与100微米聚酯微纤维相比,在这些暴露实验中鉴定出更多差异丰富的细菌。虽然长期暴露于环境现实浓度的MPs对颤蚓的存活或繁殖没有造成不利影响,但MPs暴露导致宿主微生物组改变的后果仍需进一步研究。
