Effects of Micro/Nanoplastic Particles of Different Sizes and Aggregates on Superoxide Dismutase

doi:10.16258/j.cnki.1674-5906.2026.03.003

Ecology and Environmental Sciences ›› 2026, Vol. 35 ›› Issue (3): 352-361.DOI: 10.16258/j.cnki.1674-5906.2026.03.003

• Papers on “Emerging Pollutants” • Previous Articles Next Articles

Effects of Micro/Nanoplastic Particles of Different Sizes and Aggregates on Superoxide Dismutase

PENG Jiamin¹(), YANG Chen¹^,²^,^*(), NA Pei¹, YU Wanqi¹, TANG Huili¹, DANG Zhi¹^,²

1. School of Environment and Energy, South China University of Technology, Guangzhou 510006, P. R. China
2. The Key Lab of Pollution Control and Ecosystem Restoration in Industry Clusters, Ministry of Education, Guangzhou 510006, P. R. China

Received:2025-06-11 Revised:2025-08-11 Accepted:2025-10-10 Online:2026-03-18 Published:2026-03-13

不同尺寸的微/纳米塑料及凝聚体对超氧化物歧化酶的影响

彭嘉敏¹(), 杨琛¹^,²^,^*(), 娜佩¹, 余婉琪¹, 唐蕙利¹, 党志¹^,²

1.华南理工大学环境与能源学院，广东广州 510006
2.聚集区污染控制与生态修复教育部重点实验室，广东广州 510006

通讯作者: *E-mail: cyanggz@scut.edu.cn
作者简介:彭嘉敏（2000年生），女，硕士研究生，研究方向为纳米塑料的环境行为。E-mail: pjmuu426@163.com
基金资助:
国家自然科学基金项目(42277228);国家自然科学基金项目(42077337);广东省科技计划项目(2024B1212050009)

Abstract

Abstract:

The increasing presence of micro/nanoplastics (MNPs) in diverse ecosystems, coupled with their demonstrated capacity to infiltrate the human body via ingestion, inhalation, and dermal contact, has propelled intense scientific scrutiny of their environmental fate and potential health ramifications. Once they enter the human body, these small particles can aggregate or disperse in biological fluids, leading to significant changes in their effective size, further affecting the response of the antioxidant defense system to external substances. Within this system, key enzymes, such as superoxide dismutase (SOD), which catalyze the dismutation of the highly reactive superoxide radical into oxygen and hydrogen peroxide, serve as the first line of defense. Alterations in SOD activity or structure can lead to significant oxidative damage, which is implicated in inflammation. Therefore, understanding how MNPs influence SOD is crucial for assessing their true biological impact. This study systematically investigated the interactions between polyethylene terephthalate micro/nanoplastics (PET-MNPs) with distinct primary sizes (50 nm, denoted NP50; 100 nm, denoted NP100; and 1100 nm, denoted NP1100) on SOD, focusing on the aggregation behavior of the particles in artificial lysosomal fluid (ALF) and their impact on SOD enzyme activity and function, to explore the underlying mechanisms. The analysis of aggregation in ALF showed a pronounced effect on size. The small particles (NP50 and NP100) aggregated rapidly. NP50 aggregates grew beyond 1 μm within 1 h, whereas NP100 aggregates grew more gradually. In stark contrast, NP1100 remained stable. Remarkably, the presence of SOD significantly accelerated the aggregation rates of NP50 and NP100 at all temperatures. Zeta potential analysis provided mechanistic insights: SOD addition increased the zeta potential of NP50 from −15 to −7 mV and drove NP100 potential towards neutrality, reducing electrostatic repulsion. NP1100’s zeta potential remained unchanged at −3 mV. This size-dependent potential response difference may be related to the varying interaction capacity of SOD with particle surfaces of different sizes. Smaller NP50 particles have a higher specific surface area and stronger surface reactivity, facilitating easier binding/adsorption to SOD molecules. This partially neutralized the surface negative charges and significantly increased the zeta potential. Additionally, SOD binding may compress the thickness of the particle’s electrical double layer, further reducing electrostatic repulsion and promoting aggregation. In contrast, larger NP1100 particles have a lower specific surface area, reduced probability of binding with SOD, and less affected surface charge, resulting in minimal potential changes and higher colloidal stability. Notably, NP50’s size change rate significantly exceeded those of NP100 and NP1100, indicating that the particle size profoundly influences the aggregation behavior. Smaller NP50 particles exhibited greater surface energy and collision probabilities, resulting in pronounced aggregation. In contrast, although larger particles (NP1100) have a zeta potential with a lower absolute value (|−3 mV|), their relatively lower surface energy hinders the overcoming of the DLVO energy barrier, resulting in a higher colloidal stability. In the ALF system, SOD activity responses to PET-MNPs of different sizes were significantly different. The experimental results revealed that exposure to both NP50 and NP100 decreased SOD activity, indicating that smaller PET-MNPs disrupt enzyme function more readily. In contrast, NP1100 showed negligible inhibition of SOD activity, suggesting weaker interference from larger particles. Because small PET-MNPs (NP50 and NP100) rapidly aggregate in ALF, the impact of differently sized aggregates on enzyme activity was further examined. The results showed that during early aggregation (within 5 min), when NP50 and NP100 had not yet formed distinct aggregates, the SOD activity decreased. Subsequently, as aggregates formed (>500 nm), SOD activity began to recover, possibly reflecting an adaptive regulatory mechanism of SOD. When the aggregate size exceeded 1000 nm, the SOD activity continued to increase. As NP50 and NP100 form larger aggregates, partial surface sites become occluded, reducing the direct interactions between PET-MNPs and SOD and alleviating the structural interference. This demonstrates that the aggregation state of MNPs significantly modulates their impact on enzyme activity, providing experimental evidence for understanding the relationship between the physical properties of the particles and the functional interference of the enzyme. Spectroscopic analyses revealed the structural basis for the size-dependent inhibition of SOD activity. Circular Dichroism (CD) spectroscopy showed that SOD's native secondary structure comprised 38.1% α-helix, 15.2% β-sheet, 17.0% β-turn, and 29.8% random coil. Exposure to PET-MNPs, particularly NP50 and NP100, drastically reduced α-helix content to 12.94% and 13.05%, respectively, while increasing β-sheet structures, indicating significant protein unfolding, hydrogen bond rearrangement, and loss of conformational stability. NP1100 also reduced the α-helix content to 13.49%, but to a lesser extent than the smaller particles. The greater structural perturbation by small NPs is attributed to their higher surface reactivity, which facilitates stronger interactions with critical α-helical domains of proteins. Combined with the enzymatic activity results, we inferred that exposure to small NPs, especially before or during early aggregation, disrupts SOD’s secondary structure more readily. This triggers conformational disturbances near the active center of the enzyme, impairing its catalytic function. Thus, smaller Nps, such as NP50 and NP100, or those that have not yet formed large aggregates, induce stronger structural perturbations, causing significant α-helix loss and activity impairment. In contrast, NP1100 and larger aggregates exert weaker interference because of their smaller specific surface area, limited interaction sites, and potential spatial shielding effects after aggregation, which reduce directcontact with enzyme and provide buffering protection. Three-dimensional fluorescence spectroscopy revealed that the control SOD exhibited characteristic peaks at Ex=270/Em=280 nm for the peptide backbone and Ex=215/Em=280 nm for aromatic residues. Exposure to PET-MNPs, particularly NP50 and NP100, resulted in significant fluorescence quenching and peak shifts, indicating alterations in the microenvironment of tyrosine residues and overall structural changes in the protein. NP1100 induced comparatively weaker fluorescence quenching. NP50 and NP100, which readily aggregate in ALF, likely engage in stronger electrostatic interactions with superoxide dismutase (SOD). In contrast, NP1100 exhibited higher fluorescence intensity than the NP50/NP100 groups, suggesting that its interaction with SOD may involve more superficial adsorption, causing less structural damage and better retention of the fluorescence features. These findings highlight that the “effective size” of MNPs in biological compartments, determined by their intrinsic aggregation propensity and modulated by biomolecules such as enzymes, is a crucial parameter for accurately assessing their health risks, particularly in oxidative stress pathways in the respiratory system. Future research should focus on defining the stable size ranges of different MNPs under various physiological conditions and elucidating the in vivo consequences of MNP-induced antioxidant enzyme dysfunction using cellular and animal models.

Key words: micro/nanoplastics, aggregates, superoxide dismutase, structural changes, enzyme activity

摘要：

微/纳米塑料（Micro/nanoplastics，MNPs）在环境中的归趋及健康效应日益受到关注。这些细小颗粒进入人体后，可在体液中经历凝聚或分散过程，其有效尺寸将发生显著改变，进而影响人体抗氧化系统对入侵物的响应，其中超氧化物歧化酶（Superoxide dismutase，SOD）等关键酶的活性与结构变化尤为显著。该研究选取不同粒径（50、100、1100 nm）聚对苯二甲酸乙二醇酯微/纳米塑料（PET-MNPs），探究其在人工溶酶体液（Artificial lysosomal fluid，ALF）环境中的凝聚行为以及对SOD酶活性的影响，并探讨可能的影响机制。结果表明，小尺寸颗粒（50 nm和100 nm）可快速凝聚，在1－2 h内凝聚体尺寸即可增大至1000 nm左右，大尺寸颗粒（1100 nm）则保持相对稳定。PET-MNPs及其凝聚体对SOD的干扰具有尺寸效应，小尺寸颗粒在初始凝聚阶段（5 min）即对SOD活性表现出显著抑制作用，主要与其对SOD的二级结构和酪氨酸微环境产生较大破坏有关，表现为SOD的α-螺旋含量下降和荧光信号淬灭。而大尺寸颗粒（1100 nm）及凝聚体粒径大于500 nm时，其对SOD的干扰效应相对减弱。正确评估微/纳米塑料在生理环境中的健康风险应当充分考虑其在生理环境中稳定存在的尺寸范围。

关键词: 微/纳米塑料, 凝聚体, 超氧化物歧化酶, 结构变化, 酶活

CLC Number:

X171.5

PENG Jiamin, YANG Chen, NA Pei, YU Wanqi, TANG Huili, DANG Zhi. Effects of Micro/Nanoplastic Particles of Different Sizes and Aggregates on Superoxide Dismutase[J]. Ecology and Environmental Sciences, 2026, 35(3): 352-361.

彭嘉敏, 杨琛, 娜佩, 余婉琪, 唐蕙利, 党志. 不同尺寸的微/纳米塑料及凝聚体对超氧化物歧化酶的影响[J]. 生态环境学报, 2026, 35(3): 352-361.

Figures/Tables 5

Figure 1 Material characterization of PET-MNPs

Figure 2 Changes in particle size and zeta potential of PET-MNPs in ALF

Figure 3 Effects of PET-MNPs and aggregates on SOD activity

Figure 4 CD spectra and secondary structure changes of SOD before and after interaction of PET-MNPs

Figure 5 3D fluorescence spectra of SOD in ALF before and after interaction with PET-MNPs

References 47

[1]	ADACHI T, YAMADA H, YAMADA Y, et al., 1996. Substitution of glycine for arginine-213 in extracellular-superoxide dismutase impairs affinity for heparin and endothelial cell surface[J]. The Biochemical Journal, 313(1): 235-239.
[2]	ALZABEN M, BURVE R, LOESCHNER K, et al., 2023. Nanoplastics from ground polyethylene terephthalate food containers: Genotoxicity in human lung epithelial A549 cells[J]. Mutation Research-Genetic Toxicology and Environmental Mutagenesis, 892: 50375.
[3]	ARIFUR R, ATANU S, PRAKASH Y O, et al., 2021. Potential human health risks due to environmental exposure to nano- and microplastics and knowledge gaps: A scoping review[J]. Science of the Total Environment, 757: 143872. DOI URL
[4]	CATARINO A I, MACCHIA V, SANDERSON W G, et al., 2018. Low levels of microplastics (MP) in wild mussels indicate that MP ingestion by humans is minimal compared to exposure via household fibres fallout during a meal[J]. Environmental Pollution, 237: 675-684. DOI PMID
[5]	CELIK S O, 2023. The release potential of microplastics from face masks into the aquatic environment[J]. Sustainability, 15(19): 14293. DOI URL
[6]	CESA F S, TURRA A, BARUQUE-RAMOS J, 2017. Synthetic fibers as microplastics in the marine environment: A review from textile perspective with a focus on domestic washings[J]. Science of the Total Environment, 598: 1116-1129. DOI URL
[7]	CHI Z X, ZHAO J, YOU H, et al., 2016. Study on the mechanism of interaction between phthalate acid esters and bovine hemoglobin[J]. Journal of Agricultural and Food Chemistry, 64(30): 6035-6041. DOI PMID
[8]	CHOUDHURY A, SIMNANI F Z, SINGH D, et al., 2023. Atmospheric microplastic and nanoplastic: The toxicological paradigm on the cellular system[J]. Ecotoxicology and Environmental Safety, 259: 115018. DOI URL
[9]	FERNANDO A-L L, REGIANI C-O, RIBEIRO J G, et al., 2021. Presence of airborne microplastics in human lung tissue[J]. Journal of Hazardous Materials, 416: 126124. DOI URL
[10]	FOURNIER S B, D'ERRICO J N, ADLER D S, et al., 2020. Nanopolystyrene translocation and fetal deposition after acute lung exposure during late-stage pregnancy[J]. Particle and Fibre Toxicology, 17(1): 55. DOI PMID
[11]	GOPINATH P M, SARANYA V, VIJAYAKUMAR S, et al., 2019. Assessment on interactive prospectives of nanoplastics with plasma proteins and the toxicological impacts of virgin, coronated and environmentally released-nanoplastics[J]. Scientific Reports, 9(1): 8860. DOI PMID
[12]	HE F, LIU Q, JING M, et al., 2021. Toxic mechanism on phenanthrene-induced cytotoxicity, oxidative stress and activity changes of superoxide dismutase and catalase in earthworm (Eisenia foetida): A combined molecular and cellular study[J]. Journal of Hazardous Materials, 418: 126302. DOI URL
[13]	HOLLOCZKI O, GEHRKE S, 2019. Nanoplastics can change the secondary structure of proteins[J]. Scientific Reports, 9(1): 16013. DOI PMID
[14]	HUANG X, LI Y, SHU Z, et al., 2024. High-efficiency degradation of PET plastics by glutathione s-transferase under mild conditions[J]. Environmental Science & Technology, 58(30): 13358-13369.
[15]	JO P G, CHOI Y K, CHOI C Y, 2008. Cloning and mRNA expression of antioxidant enzymes in the Pacific oyster, Crassostrea gigas in response to cadmium exposure[J]. Comparative Biochemistry and Physiology, Part C, 147(4): 460-469.
[16]	KEELE B B J, MCCORD J M, FRIDOVICH I, 1971. Further characterization of bovine superoxide dismutase and its isolation from bovine heart[J]. The Journal of Biological Chemistry, 246(9): 2875-2880. DOI URL
[17]	KEMP S J, THORLEY A J, GORELIK J, et al., 2008. Immortalization of human alveolar epithelial cells to investigate nanoparticle uptake[J]. American Journal of Respiratory Cell and Molecular Biology, 39(5): 591-597. DOI PMID
[18]	KUTRALAM-MUNIASAMY G, PEREZ-GUEVARA F, SHRUTI V C, 2022. A critical synthesis of current peer-reviewed literature on the environmental and human health impacts of COVID-19 PPE litter: New findings and next steps[J]. Journal of Hazardous Materials, 422: 126945. DOI URL
[19]	LAFORGE M, ELBIM C, FRERE C, et al., 2020. Tissue damage from neutrophil-induced oxidative stress in COVID-19[J]. Nature Reviews Immunology, 20(9): 515-516. DOI PMID
[20]	LAGANA A, VISALLI G, FACCIOLA A, et al., 2023. Uptake of breathable nano- and micro-sized polystyrene particles: Comparison of virgin and oxidised nPS/mPS in human alveolar cells[J]. Toxics, 11(8): 686. DOI URL
[21]	LEONARD S V L, LIDDLE C R, ATHERALL C A, et al., 2024. Microplastics in human blood: Polymer types, concentrations and characterisation using μFTIR[J]. Environment International, 188: 108751. DOI URL
[22]	LESLIE H A, VELZEN M J M V, BRANDSMA S H, et al., 2022. Discovery and quantification of plastic particle pollution in human blood[J]. Environment International, 163: 107199. DOI URL
[23]	LI J, DONG J W, HUANG Y S, et al., 2022b. Aggregation kinetics of TiO₂ nanoparticles in human and artificial sweat solutions: Effects of particle properties and sweat constituents[J]. Environmental Science & Technology, 56(23): 17153-17165. DOI URL
[24]	LI J, YANG X J, ZHANG Z, et al., 2021b. Aggregation kinetics of diesel soot nanoparticles in artificial and human sweat solutions: Effects of sweat constituents, pH, and temperature[J]. Journal of Hazardous Materials, 403: 123614. DOI URL
[25]	LI L, HU J L, LI J Y, et al., 2021a. Modelling air quality during the EXPLORE-YRD campaign-Part II. Regional source apportionment of ozone and PM_2.5[J]. Atmospheric Environment, 247: 118063. DOI URL
[26]	LI S C, LIU H, GAO R, et al., 2018. Aggregation kinetics of microplastics in aquatic environment: Complex roles of electrolytes, pH, and natural organic matter[J]. Environmental Pollution, 237: 126-132. DOI PMID
[27]	LI Z Q, CHANG X Q, HU M H, et al., 2022a. Is microplastic an oxidative stressor? Evidence from a meta-analysis on bivalves[J]. Journal of Hazardous Materials, 423: 127211. DOI URL
[28]	LIU Y J, HU Y B, YANG C, et al., 2019. Aggregation kinetics of UV irradiated nanoplastics in aquatic environments[J]. Water Research, 163: 114870. DOI URL
[29]	MARKLUND S L, WESTMAN N G, LUNDGREN E, et al., 1982. Copper- and zinc-containing superoxide dismutase, manganese-containing superoxide dismutase, catalase, and glutathione peroxidase in normal and neoplastic human cell lines and normal human tissues[J]. Cancer Research, 42(5): 1955-1961. PMID
[30]	MEI J X, ZHANG N, YU Y Y, et al., 2018. A novel “trifunctional protease” with reducibility, hydrolysis, and localization used for wool anti-felting treatment[J]. Applied Microbiology and Biotechnology, 102(21): 9159-9170. DOI
[31]	PELFRENE A, CAVE M R, WRAGG J, et al., 2017. In vitro investigations of human bioaccessibility from reference materials using simulated lung fluids[J]. International Journal of Environmental Research and Public Health, 14(2): 112. DOI URL
[32]	PHAN T H G, PALIOGIANNIS P, NASRALLAH G K, et al., 2021. Emerging cellular and molecular determinants of idiopathic pulmonary fibrosis[J]. Cellular and Molecular Life Sciences, 78(5): 2031-2057. DOI PMID
[33]	PROKIC M D, RADOVANOVIC T B, GAVRIC J P, et al., 2018. Ecotoxicological effects of microplastics: Examination of biomarkers, current state and future perspectives[J]. Trends in Analytical Chemistry, 111: 37-46. DOI URL
[34]	SARMITE K, LODER M G J, FRANZISKA F, et al., 2021. Airborne microplastic concentrations and deposition across the Weser River catchment[J]. Science of the Total Environment, 818: 151812. DOI URL
[35]	SHAO Z W, SU J N, DONG J W, et al., 2022. Aggregation kinetics of polystyrene nanoplastics in gastric environments: Effects of plastic properties, solution conditions, and gastric constituents[J]. Environment International, 170: 107628. DOI URL
[36]	SHIOTANI M, NODA Y, NARIMOTO K, et al., 1991. Immunohistochemical localization of superoxide dismutase in the human ovary[J]. Human Reproduction (Oxford, England), 6(10): 1349-1353. DOI URL
[37]	TAMATE K, SENGOKU K, ISHIKAWA M, 1995. The role of superoxide dismutase in the human ovary and fallopian tube[J]. Journal of Obstetrics and Gynaecology (Tokyo, Japan), 21(4): 401-409.
[38]	USUI A, KATO K, MURASE M, et al., 1992. Manganese-containing superoxide dismutase in blood and urine during open-heart surgery[J]. Japanese Circulation Journal, 56(12): 1206-1213. PMID
[39]	WANG Y Y, SHI H J, LI T, et al., 2022. Size-dependent effects of nanoplastics on structure and function of superoxide dismutase[J]. Chemosphere, 309(Part 2): 136768. DOI URL
[40]	WU D, LIU D Y, ZHANG Y, et al., 2018. Unravelling the binding mechanism of benproperine with human serum albumin: A docking, fluorometric, and thermodynamic approach[J]. European Journal of Medicinal Chemistry, 146: 245-250. DOI PMID
[41]	XU M K, HALIMU G, ZHANG Q R, et al., 2019a. Internalization and toxicity: A preliminary study of effects of nanoplastic particles on human lung epithelial cell[J]. Science of the Total Environment, 694: 133794. DOI URL
[42]	XU M C, WAN J Q, NIU Q G, et al., 2019b. PFOA and PFOS interact with superoxide dismutase and induce cytotoxicity in mouse primary hepatocytes: A combined cellular and molecular methods[J]. Environmental Research, 175: 63-70. DOI URL
[43]	XU M C, CUI Z H, ZHAO L N, et al., 2018. Characterizing the binding interactions of PFOA and PFOS with catalase at the molecular level[J]. Chemosphere, 203: 360-367. DOI PMID
[44]	ZARUS G M, CUSTODIO M, STEPHAN B, et al., 2023. Worker studies suggest unique liver carcinogenicity potential of polyvinyl chloride microplastics[J]. American Journal of Industrial Medicine, 66(12): 1033-1047. DOI PMID
[45]	ZHANG W, 2014. Nanoparticle aggregation: Principles and modeling[J]. Advances in Experimental Medicine and Biology, 811: 19-43. DOI PMID
[46]	ZHAO L N, GUO D D, LIN J, et al., 2019. Responses of catalase and superoxide dismutase to low-dose quantum dots on molecular and cellular levels[J]. Ecotoxicology and Environmental Safety, 181: 388-394. DOI PMID
[47]	崔铁峰, 李道季, 2024. 人体微纳塑料研究现状及存在的主要问题[J]. 华东师范大学学报(自然科学版) (6): 1-13.
	CUI T F, LI D J, 2024. Progress and critical issues in research on micro- and nanoplastics in human body[J]. Journal of East China Normal University (Natural Science) (6): 1-13.

Effects of Micro/Nanoplastic Particles of Different Sizes and Aggregates on Superoxide Dismutase

不同尺寸的微/纳米塑料及凝聚体对超氧化物歧化酶的影响

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