| CHEN R S, DE SHERBININ A, YE C, et al. China's soil pollution:farms on the frontline[J]. Science, 2014, 344(6185):691. |
| LARSON C. Environmental science. China gets serious about its pollutant-laden soil[J]. Science, 2014, 343(6178):1415-1416. |
| ZHAO F J, MA Y B, ZHU Y G, et al. Soil contamination in China:current status and mitigation strategies[J]. Environmental science&technology, 2015, 49(2):750-759. |
| DU B Y, ZHOU J, LU B X, et al. Environmental and human health risks from cadmium exposure near an active lead-zinc mine and a copper smelter, China[J]. Science of the total environment, 2020, 720:137585. |
| 邹长伟,江玉洁,黄虹.重金属镉的分布、暴露与健康风险评价研究进展[J].生态毒理学报, 2022, 17(6):225-243. ZOU C W, JIANG Y J, HUANG H. Distribution, exposure and health risk assessment of heavy metal cadmium:a review[J]. Asian journal of ecotoxicology, 2022, 17(6):225-243. |
| 段桂兰,崔慧灵,杨雨萍,等.重金属污染土壤中生物间相互作用及其协同修复应用[J].生物工程学报, 2020, 36(3):455-470. DUAN G L, CUI H L, YANG Y P, et al. Interactions among soil biota and their applications in synergistic bioremediation of heavy-metal contaminated soils[J]. Chinese journal of biotechnology, 2020, 36(3):455-470. |
| YANG L, LI N, KANG Y C, et al. Selenium alleviates toxicity in Amaranthus hypochondriacus by modulating the synthesis of thiol compounds and the subcellular distribution of cadmium[J]. Chemosphere, 2022, 291:133108. |
| HUANG C D, ZHANG X L, WANG K, et al. Evidence for the metal resistance of earthworm Eisenia fetida across generations (F1 and F2) under laboratory metal exposure[J]. Journal of hazardous materials, 2022, 425:128006. |
| HUANG C D, GE Y, SHEN Z Q, et al. Reveal the metal handling and resistance of earthworm Metaphire californica with different exposure history through toxicokinetic modeling[J]. Environmental pollution, 2021, 289:117954. |
| RAYMAN M P. Selenium and human health[J]. The lancet, 2012, 379(9822):1256-1268. |
| ULLAH H, LIU G J, YOUSAF B, et al. Developmental selenium exposure and health risk in daily foodstuffs:a systematic review and meta-analysis[J]. Ecotoxicology and environmental safety, 2018, 149:291-306. |
| 岳士忠.赤子爱胜蚓对硒的富集转化及其活性成分生物功能研究[D].北京:中国农业大学, 2019:37-84. YUE S Z. Bioaccumulation and transformation of selenium by Eisenia fetida and the biological function of its active components[D]. Beijing:China Agriculture University, 2019:37 -84. |
| WANG R P, YUE S Z, HUANG C D, et al. Uptake, distribution, and elimination of selenite in earthworm Eisenia fetida at sublethal concentrations based on toxicokinetic model[J]. Science of the total environment, 2023, 858:159632. |
| XU Q Y, SHAO X Q, SHI Y J, et al. Is selenium beneficial or detrimental to earthworm?Growth and metabolism responses of Eisenia fetida to Na2SeO3 exposure[J]. Science of the total environment, 2022, 807(Pt 2):150770. |
| GAN X Y, HUANG J C, ZHANG M P, et al. Remediation of selenium-contaminated soil through combined use of earthworm Eisenia fetida and organic materials[J]. Journal of hazardous materials, 2021, 405:124212. |
| SNIDER G W, RUGGLES E, KHAN N, et al. Selenocysteine confers resistance to inactivation by oxidation in thioredoxin reductase:comparison of selenium and sulfur enzymes[J]. Biochemistry, 2013, 52(32):5472-5481. |
| WYATT L H, DIRINGER S E, ROGERS L A, et al. Antagonistic growth effects of mercury and selenium in Caenorhabditis elegans are chemical-species-dependent and do not depend on internal Hg/Se ratios[J]. Environmental science&technology, 2016, 50(6):3256-3264. |
| Organization for Economic Co-operation and Development (OECD). Test No. 317:bioaccumulation in terrestrial oligochaetes[S]. Paris:OECD, 2010. |
| YUE S Z, HUANG C D, WANG R P, et al. Selenium toxicity, bioaccumulation, and distribution in earthworms (Eisenia fetida) exposed to different substrates[J]. Ecotoxicology and environmental safety, 2021, 217:112250. |
| 赵丽,邱江平,沈嘉林,等.重金属镉、铜对蚯蚓的急性毒性试验[J].上海交通大学学报(农业科学版), 2005, 23(4):366-370. ZHAO L, QIU J P, SHEN J L, et al. Acute toxicity of heavy metal cadmium and copper to earthworms[J]. Journal of Shanghai Jiao Tong University (agricultural science), 2005, 23(4):366-370. |
| WANG K, QIAO Y H, ZHANG H Q, et al. Influence of metal-contamination on distribution in subcellular fractions of the earthworm (Metaphire californica) from Hunan Province, China[J]. Journal of environmental sciences, 2018, 73:127-137. |
| YUE S Z, WANG R P, HUANG C D, et al. Toxicokinetics of selenate in earthworm sub-tissues and potential bio-accessibility assessment of earthworm-derived selenium[J]. Ecotoxicology and environmental safety, 2024, 281:116643. |
| TANG R G, LAN P, DING C F, et al. A new perspective on the toxicity of arsenic-contaminated soil:tandem mass tag proteomics and metabolomics in earthworms[J]. Journal of hazardous materials, 2020, 398:122825. |
| 穆磊,吴星,陈红星,等.硒预暴露对夹杂带丝蚓铜累积及毒性的影响[J].生态学杂志, 2017, 36(8):2282-2288. MU L, WU X, CHEN H X, et al. Effects of pre-exposure to selenium on the accumulation and toxicity of copper in Lumbriculus variegatus[J]. Chinese journal of ecology, 2017, 36(8):2282-2288. |
| 杨莹,王志敏,杜晶晶,等.砷对蚯蚓的滤纸接触毒性及硒的调节作用[J].中国农学通报, 2024, 40(17):49-55. YANG Y, WANG Z M, DU J J, et al. The contact toxicity of arsenic to earthworms and regulatory effect of selenium[J]. Chinese agricultural science bulletin, 2024, 40(17):49-55. |
| MARCHÁN-MORENO C, QUEIPO-ABAD S, CORNS W T, et al. Assessment of dietary selenium and its role in mercury fate in cultured fish rainbow trout with two sustainable aquafeeds[J]. Food chemistry, 2024, 447:138865. |
| MONIRUZZAMAN M, PARK G, YUN H, et al. Synergistic effects of dietary vitamin E and selenomethionine on growth performance and tissue methylmercury accumulation on mercury-induced toxicity in juvenile olive flounder, Paralichthys olivaceus(Temminck et Schlegel)[J]. Aquaculture research, 2017, 48(2):570-580. |
| IBRAHIM A T A, BANAEE M, SUREDA A. Selenium protection against mercury toxicity on the male reproductive system of Clarias gariepinus[J]. Comparative biochemistry and physiology part C:toxicology&pharmacology, 2019, 225:108583. |
| LUO K, ZHOU L Y, XIE C, et al. High-fidelity fluorescent probes for visualizing the inhibitory behavior of selenium on cadmium uptake in rice[J]. Journal of hazardous materials, 2023, 457:131748. |
| WU K Y, WANG L Z, WU Z H, et al. Selenite reduced cadmium uptake, interfered signal transduction of endogenous phytohormones, and stimulated secretion of tartaric acid based on a combined analysis of non-invasive micro-test technique, transcriptome and metabolome[J]. Plant physiology and biochemistry, 2024, 206:108107. |
| ULLAH S, DEPAR N, KHAN D, et al. Selenate and selenite induced differential morphophysiological modifications to mitigate arsenic toxicity and uptake by wheat[J]. Soil and sediment contamination:an international journal, 2024, 33(3):331-352. |
| SHI W Y, SUN S B, LIU H W, et al. Guiding bar motif of thioredoxin reductase 1 modulates enzymatic activity and inhibitor binding by communicating with the co-factor FAD and regulating the flexible C-terminal redox motif[J]. Redox biology, 2024, 70:103050. |
| WANG Y, WU Y C, LUO K, et al. The protective effects of selenium on cadmium-induced oxidative stress and apoptosis via mitochondria pathway in mice kidney[J]. Food and chemical toxicology, 2013, 58:61-67. |
| TOMZA-MARCINIAK A, PILARCZYK B, DROZD R, et al. Selenium and mercury concentrations, Se:Hg molar ratios and their effect on the antioxidant system in wild mammals[J]. Environmental pollution, 2023, 322:121234. |
| 赵骞,刘桐序,李琦,等.硒对铅中毒诱导蛋鸡肾脏炎症损伤缓解作用研究[J].东北农业大学学报, 2021, 52(9):47-54. ZHAO Q, LIU T X, LI Q, et al. Effects of selenium relieving lead-induced inflammation in kidneys of laying hens[J]. Journal of Northeast Agricultural University, 2021, 52(9):47-54. |
| RAHMAN M M, HOSSAIN K F B, BANIK S, et al. Selenium and zinc protections against metal-(loids)-induced toxicity and disease manifestations:a review[J]. Ecotoxicology and environmental safety, 2019, 168:146-163. |
| HUANG G X, DING C F, LI Y S, et al. Selenium enhances iron plaque formation by elevating the radial oxygen loss of roots to reduce cadmium accumulation in rice (Oryza sativa L.)[J]. Journal of hazardous materials, 2020, 398:122860. |
| COEURDASSIER M, SCHEIFLER R, DE VAUFLEURY A, et al. Earthworms influence metal transfer from soil to snails[J]. Applied soil ecology, 2007, 35(2):302-310. |
| VIJVER M G, WOLTERBEEK H T, VINK J P M, et al. Surface adsorption of metals onto the earthworm Lumbricus rubellus and the isopod Porcellio scaber is negligible compared to absorption in the body[J]. Science of the total environment, 2005, 340(1/2/3):271-280. |
| SUN H J, RATHINASABAPATHI B, WU B, et al. Arsenic and selenium toxicity and their interactive effects in humans[J]. Environment international, 2014, 69:148-158. |
| ZWOLAK I. The role of selenium in arsenic and cadmium toxicity:an updated review of scientific literature[J]. Biological trace element research, 2020, 193(1):44-63. |
| MORGAN A J, TURNER M P, MORGAN J E. Morphological plasticity in metal-sequestering earthworm chloragocytes:morphometric electron microscopy provides a biomarker of exposure in field populations[J]. Environmental toxicology and chemistry, 2002, 21(3):610-618. |
| MORGAN J E, MORGAN A J. The distribution and intracellular compartmentation of metals in the endogeic earthworm Aporrectodea caliginosa sampled from an unpolluted and a metal-contaminated site[J]. Environmental pollution, 1998, 99(2):167-175. |
| BEDNARSKA A J,ŚWIĄTEK Z. Subcellular partitioning of cadmium and zinc in mealworm beetle (Tenebrio molitor) larvae exposed to metal-contaminated flour[J]. Ecotoxicology and environmental safety, 2016, 133:82-89. |
| PEDERSEN S A, KRISTIANSEN E, ANDERSEN R A, et al. Isolation and preliminary characterization of a Cd-binding protein from Tenebrio molitor(Coleoptera)[J]. Comparative biochemistry and physiology part C:toxicology&pharmacology, 2007, 145(3):457-463. |
| LI L Z, ZHOU D M, WANG P, et al. Subcellular distribution of Cd and Pb in earthworm Eisenia fetida as affected by Ca2+ ions and Cd-Pb interaction[J]. Ecotoxicology and environmental safety, 2008, 71(3):632-637. |
| JASKULAK M, RORAT A, KURIANSKA-PIATEK L, et al. Species-specific Cd-detoxification mechanisms in lumbricid earthworms Eisenia andrei, Eisenia fetida and their hybrids[J]. Ecotoxicology and environmental safety, 2021, 208:111425. |
| STVRZENBAUM S R, GEORGIEV O, JOHN MORGAN A, et al. Cadmium detoxification in earthworms:from genes to cells[J]. Environmental science&technology, 2004, 38(23):6283-6289. |
| ZHANG X F, HU Z H, YAN T X, et al. Arbuscular mycorrhizal fungi alleviate Cd phytotoxicity by altering Cd subcellular distribution and chemical forms in Zea mays[J]. Ecotoxicology and environmental safety, 2019, 171:352-360. |
| LIEBEKE M, GARCIA-PEREZ I, ANDERSON C J, et al. Earthworms produce phytochelatins in response to arsenic[J]. PLoS One, 2013, 8(11):e81271. |
| 刘彩凤,史刚荣,余如刚,等.硅缓解植物镉毒害的生理生态机制[J].生态学报, 2017, 37(23):7799-7810. LIU C F, SHI G R, YU R G, et al. Eco-physiological mechanisms of silicon-induced alleviation of cadmium toxicity in plants:a review[J]. Acta ecologica sinica, 2017, 37(23):7799-7810. |
| QIN Y Y, WANG Y R, SHI P T, et al. Interactive effects of selenium and arsenic on their accumulation, translocation, arsenic and selenium species, and subcellular distribution in Brassica vegetables[J]. Journal of soil science and plant nutrition, 2024, 24(2):4000-4016. |
| WALLACE W G, LUOMA S N. Subcellular compartmentalization of Cd and Zn in two bivalves. Ⅱ. Significance of trophically available metal (TAM)[J]. Marine ecology progress series, 2003, 257:125-137. |
| RAINBOW P S. Trace metal concentrations in aquatic invertebrates:why and so what?[J]. Environmental pollution, 2002, 120(3):497-507. |