Abstract
Marine plastic pollution represents a key environmental concern. Whilst ecotoxicological data for plastic is increasingly available, its impact upon marine phytoplankton remains unclear. Owing to their predicted abundance in the marine environment and likely interactions with phytoplankton, here we focus on the smaller fraction of plastic particles (~50 nm and ~2 µm polystyrene spheres). Exposure of natural phytoplankton communities and laboratory cultures revealed that plastic exposure does not follow traditional trends in ecotoxicological research, since large phytoplankton appear particularly susceptible towards plastics exposure despite their lower surface-to-volume ratios. Cell declines appear driven by hetero-aggregation and co-sedimentation of cells with plastic particles, recorded visually and demonstrated using confocal microscopy. As a consequence, plastic exposure also caused disruption to photosynthetic functioning, as determined by both photosynthetic efficiency and high throughput proteomics. Negative effects upon phytoplankton are recorded at concentrations orders of magnitude above those estimated in the environment. Hence, it is likely that impacts of NPs and MPs are exacerbated at the high concentrations typically used in ecotoxicological research (i.e., mg L-1).
Highlights
The occurrence of plastic debris within the global ocean appears ubiquitous and represents a major environmental concern (Cole et al, 2011; Andrady, 2011)
Exposure of natural marine communities to NPs and mi crospheres (MPs) revealed significant impacts upon phytoplankton growth related to cell size, being larger phytoplankton more susceptible to plastic exposure than smaller phototrophs
Natural seawater (NSW) was incubated with NPs or MPs at a range of concentrations (i.e., 0.00005–0.05% w/v, equating to 0.5–500 mg L-1) and phytoplankton growth was monitored by flow cytometry for a period of 72 h (Fig. 1)
Summary
The occurrence of plastic debris within the global ocean appears ubiquitous and represents a major environmental concern (Cole et al, 2011; Andrady, 2011). Microplastics are believed likely to continually fragment in the nat ural environment until completely mineralised, forming particles of an ever-decreasing size, eventually giving rise to nanoplastics (
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