Reef-building corals act as long-term sink for microplastic

The pollution of the marine environment with microplastics is pervasive. However, microplastic concentrations in the seawater are lower than the number of particles entering the oceans, suggesting that plastic particles accumulate in environmental sinks. Yet, the exact long-term sinks related to the “missing plastic” phenomenon are barely explored. Sediments in nearshore biogenic habitats are known to trap large amounts of microplastics, but also the three-dimensional structures of coral reefs might serve as unique, living long-term sinks. The main framework builders, reef-building corals, have been shown to ingest and overgrow microplastics, potentially leading to a deposition of particles in reef structures. However, little is known about the number of deposited particles and the underlying processes determining the permanent deposition in the coral skeletons. To test whether corals may act as living long-term sink for microplastic, we exposed four reef-building coral species to polyethylene microplastics (200 particles L^?1) in an 18-month laboratory experiment. We found microplastics in all treatment specimens, with low numbers of particles trapped in the coral tissue (up to 2 particles per cm²) and much higher numbers in the skeleton (up to 84 particles per cm³). The numbers of particles accumulated in the coral skeletons were mainly related to coral growth (i.e., skeletal growth in volume), suggesting that deposition is a regularly occurring stochastic process. We estimate that reef-building corals may remove 0.09%–2.82% of the bioavailable microplastics from tropical shallow-reef waters per year. Our study shows for the first time that microplastic particles accumulate permanently in a biological sink, helping to explain the “missing plastic” phenomenon. This highlights the importance of coral reefs for the ecological balance of the oceans and reinforces the need to protect them, not only to mitigate the effects of climate change but also to preserve their ecosystem services as long-term sink for microplastic.     

Environmental exposure more than plastic composition shapes marine microplastic-associated bacterial communities in Pacific versus Caribbean field incubations

Microplastics have arisen as a global threat to marine ecosystems. In this study, we explored the role that plastic polymer type, incubation time and geographic location have on shaping the microbial community adhered to the microplastics, termed the plastisphere. We performed detailed bacterial plastisphere community analyses on microplastics of six different household plastic polymers, serving as proxies of secondary microplastics, incubated for 6 weeks in coastal Pacific waters. These bacterial communities were compared to the plastisphere communities grown on identical microplastic particles incubated in the coastal Caribbean Sea at Bocas del Toro, Panama. Ribosomal gene sequencing analyses revealed that bacterial community composition did not exhibit a significant preference for plastic type at either site but was instead driven by the incubation time and geographic location. We identified a ‘core plastisphere’ composed of 57 amplicon sequence variants common to all plastic types, incubation times and locations, with possible synergies between taxa. This study contributes to our understanding of the importance of geography in addition to exposure time, in the composition of the plastisphere.     

Nylon microfibers develop a distinct plastisphere but have no apparent effects on the gut microbiome or gut tissue status in the blue mussel,Mytilus edulis

Ingestion of microplastics (MP) by suspension-feeding bivalves has been well-documented. However, it is unclear whether exposure to MP could damage the stomach and digestive gland (gut) of these animals, causing ramifications for organism and ecosystem health. Here, we show no apparent effects of nylon microfiber (MF) ingestion on the gut microbiome or digestive tissues of the blue mussel, Mytilus edulis. We exposed mussels to two low concentrations (50 and 100 particles/L) of either nylon MF or Spartina spp. particles (dried, ground marsh grass), ca. 250–500 μm in length, or a no particle control laboratory treatment for 21 days. Results showed that nylon MF, when aged in coarsely filtered seawater, developed a different microbial community than Spartina spp. particles and seawater, however, even after exposure to this different community, mussel gut microbial communities resisted disturbance from nylon MF. The microbial communities of experimental mussels clustered together in ordination and were similar in taxonomic composition and measures of alpha diversity. Additionally, there was no evidence of damage to gut tissues after ingestion of nylon MF or Spartina spp. Post-ingestive particle processing likely mediated a short gut retention time of these relatively large particles, contributing to the negligible treatment effects.     

微塑料附着微生物研究进展

近年来,微塑料引起的环境污染已经成为一个全球性的问题,在海洋环境中,微生物可以附着于微塑料表面形成生物被膜。已有研究表明生物被膜可以为生活在其内部的细菌提供保护,被膜中可能富集了对人体或者水生生物有害的致病菌,且频繁的基因交流可能产生更多耐药菌。微塑料表面附着的微生物,能借助大洋环流随微塑料在海洋中迁徙,进而可能引起微生物入侵事件的发生。主要对微塑料与生物被膜之间的相互作用、微塑料与附着在其表面的塑料降解菌、微塑料与致病菌、微塑料对微生物迁徙的影响,以及微塑料表面生物被膜中耐药基因的扩散进行综述,对微塑料附着微生物未来研究方向进行了展望,为更好地了解海洋微塑料污染提供参考。     

Unravelling the emerging threats of microplastics to agroecosystems

Reviews in Environmental Science and Bio/Technology - In the past few decades, pollution from microplastics has emerged as an important issue on a global scale. These plastic particles are mainly...     

典型河蟹养殖池塘不同养殖阶段水体微塑料特征

研究对典型河蟹养殖池塘水体在不同养殖阶段的微塑料丰度和赋存特征进行了研究。河蟹养殖池塘中微塑料丰度处于200—1640个/m³的水平,在全国与世界范围内处于中等水平。养殖前中期微塑料丰度较低,而养殖末期微塑料丰度较高。河蟹养殖周期中的引水和排水过程、养殖过程中塑料制品的使用和老化及养殖过程中水环境的变化都可能对河蟹养殖池塘的微塑料丰度变化产生影响。而养殖过程不仅影响了微塑料丰度,还影响了河蟹养殖池塘的微塑料特征,微塑料的形状、粒径、颜色及聚合物类型都在不同养殖期发生变化。研究进一步揭示了水样养殖过程中微塑料生成和变化的过程和机制。养殖末期较高的微塑料丰度表明可能需要关注养殖尾水排放对天然水体微塑料赋存的影响。     

Microplastics as an emerging threat to terrestrial ecosystems

Microplastics (plastics <5 mm, including nanoplastics which are <0.1 μm) originate from the fragmentation of large plastic litter or from direct environmental emission. Their potential impacts in terrestrial ecosystems remain largely unexplored despite numerous reported effects on marine organisms. Most plastics arriving in the oceans were produced, used, and often disposed on land. Hence, it is within terrestrial systems that microplastics might first interact with biota eliciting ecologically relevant impacts. This article introduces the pervasive microplastic contamination as a potential agent of global change in terrestrial systems, highlights the physical and chemical nature of the respective observed effects, and discusses the broad toxicity of nanoplastics derived from plastic breakdown. Making relevant links to the fate of microplastics in aquatic continental systems, we here present new insights into the mechanisms of impacts on terrestrial geochemistry, the biophysical environment, and ecotoxicology. Broad changes in continental environments are possible even in particle‐rich habitats such as soils. Furthermore, there is a growing body of evidence indicating that microplastics interact with terrestrial organisms that mediate essential ecosystem services and functions, such as soil dwelling invertebrates, terrestrial fungi, and plant‐pollinators. Therefore, research is needed to clarify the terrestrial fate and effects of microplastics. We suggest that due to the widespread presence, environmental persistence, and various interactions with continental biota, microplastic pollution might represent an emerging global change threat to terrestrial ecosystems.     

Sorption of fluorescent polystyrene microplastic particles to edible seaweed <Emphasis Type="Italic">Fucus vesiculosus</Emphasis>

Increased global demands for food have raised interest for seaweed as a healthy and sustainable food source. At the same time, the large amounts of microplastic in the oceans have raised concern in relation to pollution of seafood including sea vegetables. The aim of this study was to examine sorption of fluorescent polystyrene (PS) microplastic particles to edible macroalga (seaweed) Fucus vesiculosus, and to investigate to what extent adsorbed PS particles could be washed off, using an industrial relevant method. PS microplastic particles (diameter of 20 μm) were used in a concentration of 2.65 mg L^?1 (corresponding to 597 particles per mL) in filtrated seawater (50 mL) to treat F. vesiculosus distal tips in blue cap flasks (100 mL) placed in a rotary box for 2 h. Results showed sorption of PS microplastic particles to F. vesiculosus analysed by microscopy and a significant reduction of 94.5% by washing. These results were based on high microplastic concentrations, not comparable to natural conditions/concentrations. Nonetheless, this study provides methodological and mechanistic insights into procedures for investigating the sorption of microplastics to seaweed, for which there is currently no established standardised method.     

鄱阳湖主要入湖段典型底栖动物体内微塑料累积特征

以鄱阳湖-饶河和鄱阳湖-赣江中支两个主要入湖段典型底栖动物(河蚬、圆顶珠蚌、中国圆田螺)为对象,通过组织消解、滤膜过滤分离和显微镜检筛分微塑料(粒径<5mm),分析底栖动物体内微塑料的累积特征。结果表明:三种底栖动物体内均有微塑料淀积且主要淀积于消化道组织中,不同物种淀积丰度表现为河蚬>中国圆田螺>圆顶珠蚌;淀积的微塑料类型包括颗粒类、碎片类、薄膜类和纤维类,其中以纤维类为主;微塑料颜色主要有透明、蓝、红、紫;粒径以<1 mm的丰度最高,且随粒径增大丰度呈递减的趋势;空间尺度上,饶河入湖段底栖动物体内微塑料丰度高于赣江中支入湖段。本研究表明,鄱阳湖微塑料污染已造成底栖动物体内微塑料的累积,湖水产品的食用需要谨慎,但与国内外其他研究相比,本次研究区域的底栖动物处于中等微塑料污染。     

城乡景观中土壤生态系统微塑料的来源、迁移特征及其风险

土壤微塑料污染的持久性、复杂性及其对土壤生态系统的影响受到越来越广泛的关注,但对其来源、迁移过程等仍有许多问题尚未理清。从复合生态系统的角度,通过对城乡景观中土壤微塑料的来源、迁移过程及其风险等相关研究进展进行了系统梳理,分析了城乡不同景观中土壤微塑料的主要来源和特点,讨论了土壤微塑料在城乡景观中的迁移特征及其驱动力,探讨了土壤微塑料在城乡景观中的生态和健康风险。今后需进一步明确城乡景观中土壤微塑料污染的物质流过程与环境归趋特征,加强微塑料对土壤生态系统的作用过程及生态系统服务影响的研究,揭示土壤微塑料对人类健康的直接或间接影响,建立城乡复合生态系统土壤微塑料污染预测模型,以维护土壤生态安全与人居环境健康。     

A study on the cytoplasmic granules of the pericardial gland cells of some bivalve molluscs

The pericardial glands of three bivalve molluscs are composed of convoluted epithelium that appears as pouches on the auricles of Mytilus and as tubules in the connective tissue at the anterior-lateral sides of the pericardial cavity of Mercenaria and Anodonta. The pericardial gland cells are attached to each other by many randomly placed desmosome-like cell junctions and gap junctions. Belt-desmosomes that are characteristic of epithelial cells were not observed. The basal membrane of these cells is invaginated producing complex interdigitating cytoplasmic processes and filtration slits. The pericardial gland cells stain for the presence of iron with Prussian blue stain. Electron-dense and electron-lucent granules of various diameters are present in the cytoplasm. Many electron-dense granules contain ferritin-like particles in which the presence of iron has been demonstrated by microanalysis. It is suggested that these particles are the iron storage protein ferritin since they contain iron, and are water soluble, heat stable, and morphologically similar to mammalian ferritin. Ferritin particles are probably both synthesized and broken down by the pericardial gland cells; thus the pericardial gland cells may be involved in iron homeostasis in these molluscs.     

Microplastic effects on carbon cycling processes in soils

Microplastics (MPs), plastic particles <5 mm, are found in environments, including terrestrial ecosystems, planetwide. Most research so far has focused on ecotoxicology, examining effects on performance of soil biota in controlled settings. As research pivots to a more ecosystem and global change perspective, questions about soil-borne biogeochemical cycles become important. MPs can affect the carbon cycle in numerous ways, for example, by being carbon themselves and by influencing soil microbial processes, plant growth, or litter decomposition. Great uncertainty surrounds nano-sized plastic particles, an expected by-product of further fragmentation of MPs. A major concerted effort is required to understand the pervasive effects of MPs on the functioning of soils and terrestrial ecosystems; importantly, such research needs to capture the immense diversity of these particles in terms of chemistry, aging, size, and shape.

This Essay proposes that a major concerted effort is required to understand the pervasive effects of microplastics on the functioning of soils and terrestrial ecosystems, including the immense diversity of microplastic particles in terms of their chemistry, aging, size, and shape.     

Plastic Pollution in the World's Oceans: More than 5 Trillion Plastic Pieces Weighing over 250,000 Tons Afloat at Sea

Plastic pollution is ubiquitous throughout the marine environment, yet estimates of the global abundance and weight of floating plastics have lacked data, particularly from the Southern Hemisphere and remote regions. Here we report an estimate of the total number of plastic particles and their weight floating in the world''s oceans from 24 expeditions (2007–2013) across all five sub-tropical gyres, costal Australia, Bay of Bengal and the Mediterranean Sea conducting surface net tows (N = 680) and visual survey transects of large plastic debris (N = 891). Using an oceanographic model of floating debris dispersal calibrated by our data, and correcting for wind-driven vertical mixing, we estimate a minimum of 5.25 trillion particles weighing 268,940 tons. When comparing between four size classes, two microplastic <4.75 mm and meso- and macroplastic >4.75 mm, a tremendous loss of microplastics is observed from the sea surface compared to expected rates of fragmentation, suggesting there are mechanisms at play that remove <4.75 mm plastic particles from the ocean surface.     

Mitochondrial contribution to metabolic changes in the digestive gland of Mytilus galloprovincialis during anaerobiosis

The activities of several enzymes and the levels of metabolites have been measured in the digestive gland of Mytilus galloprovincialis exposed to increasing hypoxia from 7 to 168 hr. A sharp decrease of pyruvate kinase was observed after 7 hr. The anoxic enzyme showed increased Km for phosphoenolpyruvate and decreased apparent Ki for alanine. Glyoxalase I was constant after up to 72 hr of exposure and then decreased. Phosphoenolpyruvate carboxykinase and alanopine dehydrogenase decreased. The metabolites alanine and succinate increased with hypoxia time, whereas D- and L-lactic and aspartic acids were undetectable and constant respectively. Mitochondrial formation of pyruvate from D-lactate was demonstrated in intact mitochondria isolated from the digestive gland of Mytilus galloprovincialis. The significance of the observed enzyme and metabolite changes in hypoxia is discussed in comparison with other invertebrate organisms. The role of mitochondria in the overall adaptive strategy of Mytilus galloprovincialis is discussed. J. Exp. Zool. 286:107-113, 2000.     

Microplastics and freshwater microalgae: what do we know so far?

The constant entry of microplastics in several environmental matrices has been of great concern to the scientific community and to society in general, mainly due to the mysteries that surround the implications of this pollutant in the environment. Freshwater ecosystems are resources especially susceptible to variations in environmental quality, and the lack of data on the impacts caused by plastic fragments exacerbates the vulnerability of this environment. Considering the results of other studies, which demonstrate the increasing entry of polymeric fragments in the aquatic environment can lead to algae growth inhibition, an investigation was carried out to determine the current state of research on the interaction between microplastics and freshwater microalgae. In total, 20 scientific articles were analyzed. Different species were subjected to toxicological tests under controlled conditions in the laboratory with small microplastics (size range between 0.1 and 1000 µm), primary and secondary microplastics of different types of polymer. Four toxicity class of indicators were chosen to assess the microalgae response to exposure to microplastic in the selected studies: growth inhibition; photosynthetic activity; pigment analysis; and enzymatic activity and oxidative stress. In this review, a critical analysis is made on the effects of the shape, size, concentration, and duration of exposure to microplastics and research gaps are identified to guide future research priorities in this area of study.

     

微塑料对稻田土壤温室气体排放和微生物群落的影响

微塑料因在土壤环境中广泛存在及其潜在的生态风险而受到越来越多的关注。微塑料的赋存会改变土壤理化性质,并对土壤微生物群落及其驱动的生物地球化学过程产生影响,而相关研究尚处于起步阶段。可生物降解塑料作为传统塑料的替代品,越来越多地应用于农业活动,并释放到土壤中。然而,可生物降解微塑料对土壤微生物特性产生影响的研究鲜有报道。基于此,本试验以我国三江平原水稻田土壤为研究对象,选取了2种常见的微塑料为试验材料,分别为传统型微塑料聚丙烯(Polypropylene,PP)和可降解微塑料聚乳酸(Polylactic acid,PLA),进行了为期41d的微宇宙培养实验,旨在分析不同浓度与类型的微塑料对土壤可溶性有机碳(Dissolved Organic Carbon,DOC)含量及官能团特征、温室气体排放以及微生物群落结构的差异性影响。结果表明,传统型微塑料PP与可降解微塑料PLA添加均对土壤理化性质与微生物群落产生显著影响。其中,微塑料添加大体上增加了土壤DOC含量,PLA的促进作用较为明显,且增加含量与微塑料添加量呈正相关;PP和PLA均影响土壤DOC分子结构,削弱了土壤团聚化程度并促进了大分子量DOC化合物的生成;微塑料的添加促进土壤CH₄排放,而有效抑制了土壤CO₂排放;微塑料显著改变了土壤细菌和真菌群落的丰富度与多样性。相关分析结果表明,土壤CO₂累计排放量与芳香族化合物结构及疏水性等官能团特征、变形菌门(Proteobacteria)与放线菌门(Actinobacteria)均呈显著正相关关系。以上结果表明,微塑料添加改变了土壤DOC含量及官能团特征与微生物环境,进而影响土壤温室气体排放。本研究为今后微塑料对土壤地球化学和微生物特性的影响研究提供了科学的思路,同时也有助于评估微塑料对土壤生态系统的生态风险。     

Microplastics and anthropogenic fibre concentrations in lakes reflect surrounding land use

Pollution from microplastics and anthropogenic fibres threatens lakes, but we know little about what factors predict its accumulation. Lakes may be especially contaminated because of long water retention times and proximity to pollution sources. Here, we surveyed anthropogenic microparticles, i.e., microplastics and anthropogenic fibres, in surface waters of 67 European lakes spanning 30° of latitude and large environmental gradients. By collating data from >2,100 published net tows, we found that microparticle concentrations in our field survey were higher than previously reported in lakes and comparable to rivers and oceans. We then related microparticle concentrations in our field survey to surrounding land use, water chemistry, and plastic emissions to sites estimated from local hydrology, population density, and waste production. Microparticle concentrations in European lakes quadrupled as both estimated mismanaged waste inputs and wastewater treatment loads increased in catchments. Concentrations decreased by 2 and 5 times over the range of surrounding forest cover and potential in-lake biodegradation, respectively. As anthropogenic debris continues to pollute the environment, our data will help contextualise future work, and our models can inform control and remediation efforts.

Pollution from microplastics and anthropogenic fibres threatens lakes, but we know little about what factors predict its accumulation. This study uses a survey of 67 European lakes spanning 30° of latitude to show that economic and environmental indicators predict the pollution of lakes by anthropogenic microparticles.     

Cutaneous eccrine glands of the foot pads of the small Madagascan tenrec (<Emphasis Type="Italic">Echinops telfairi,</Emphasis> Insectivora,Tenrecidae): skin glands in a primitive mammal

In order to find correlations between skin gland morphology and specific ethological features, the cutaneous glands of the foot pads of the primitive mammal the Madagascan tenrec, Echinops telfairi, were studied by histological and various histochemical methods as well as by electron microscopy. In the foot pads specific eccrine skin glands occurred consisting of coiled ducts and tubular secretory portions, the lumina of which were considerably wider than in primate sweat glands. The secretory tubules were composed of branched myoepithelial cells and glandular cells. The latter contained abundant mitochondria, large amounts of glycogen particles and few secretory granules as well as individual heterolysosomes and myelin bodies. The lateral cell membrane was marked by extensive interdigitations. The apical membranes of all glandular cells contained proteoglycans with sulfated and carboxylated groups containing N-acetyl-glucosamine, N-acetyl-galactosamine, galactose and mannose. The expression pattern of cytokeratins of the glandular epithelium was variable and showed similarities to that of the human eccrine glands. Tubulin, vinculin and actin were expressed in the glandular epithelium. The secretory cells showed positive reactions with antibodies against antimicrobial peptides and IgA. A positive reaction was observed with antibodies against the androgen receptor. The PCNA and TUNEL reactions indicated that the tubular skin glands of Echinops are made up of a slowly renewing tissue. We conclude that the glands fulfill several functions: production of a fluid-rich secretory product, which may prevent slipping of the foot pads on the substrate during running or climbing, secretion of antimicrobial peptides and proteins, and playing a role in thermoregulation.We thank the Fendt Foundation for financial support     

Egestion rates of microplastic fibres in fish scaled to in situ concentration and fish density

1. Microplastics (particles <5 mm) are commonly found in aquatic organisms across taxonomic groups and ecosystems. However, the egestion rate of microplastics from aquatic organisms and how egestion rates compare to other rates of microplastic movement in the environment are sparsely documented.
2. We fed microplastic fibres to round gobies (Neogobius melanostomus), an abundant, invasive species in the Laurentian Great Lakes. We conducted two trials where round gobies were fed microplastic-containing food either a single time (1 day) or every day over 7 days.
3. There was no difference in microplastic egestion rates from the 1 day or 7 day feeding trials, suggesting no impact of duration of exposure on egestion (exponential decay rate = −0.055 [±0.016 SE] and −0.040 [±0.007 SE], respectively). Turnover time of microplastics (i.e., average time from ingestion to egestion) in the gut ranged from 18.2 to 25.0 hr, similar to published values for other freshwater taxa.
4. We also measured microplastics in the digestive tracts of round gobies collected directly from Lake Michigan, U.S.A. Using published values for round goby density and microplastic concentration at the study sites, we calculated areal egestion rate by round gobies (no. particles m^–2 day^–1), and compared it to riverine microplastic export (no. particles m^–2 day^–1). Both area-based rates were of the same order of magnitude, suggesting that round goby egestion could be an important, and potentially overlooked component of microplastic dynamics at the ecosystem scale.
5. Animal egestion is well-known as a major component of nutrient and carbon cycling. However, direct measurements of microplastic fluxes in the environment that include animal egestion rates are uncommon. An ecosystem ecology approach is needed to meet the emerging challenge of generating microplastic budgets for freshwater environments and elsewhere, thereby informing management and mitigation of plastic pollution at a global scale.

     

长山列岛邻近海域沉积环境微塑料的分布特征

长山列岛(长岛)属于典型的海岛生态系统,随着海洋微塑料污染日益加剧,其周边海域沉积环境中的微塑料分布现状值得深入探究。文章以长岛养殖区和航道沉积物为研究对象,利用显微镜观察和傅里叶变换红外光谱测定等方法对沉积物中的微塑料进行分析。结果表明,长岛邻近海域沉积物中微塑料的丰度为133.14—499.82个/kg,平均丰度为252.59个/kg。微塑料的尺寸以<500μm为主,占微塑料总丰度的70%以上;微塑料的形状以颗粒状为主,其次为碎片状、纤维状和小球状;微塑料的颜色以透明色为主;微塑料的聚合物类型以玻璃纸为主,其次为聚乙烯、聚对苯二甲酸乙二酯和纤维素等。由于长岛地处黄渤海交汇处,整体水动力交换能力较好。虽然长岛南部水域水体流动性弱于北部,且南部水域距离入海河流更近,受陆源输入的影响更大,但是长岛南部水域沉积物中微塑料的丰度并未显著高于北部。研究为长岛海洋生态环境中微塑料污染的科学评估与管理提供科学依据。