374                                  渔  业  研  究                                     第 47 卷

              ［  5  ］   Li T, Fan X T, Cai M H, et al. Advances in investigating  growth  rates,  community  composition,  and  microcystin
                   microcystin-induced liver toxicity and underlying mech-  concentration  in  the  western  basin  of  Lake  Erie[J].
                   anisms[J]. Science of the Total Environment, 2023, 905:  Harmful Algae, 2023, 123: 102382.
                   167167.                                    ［16］   王镇. 铜、锌离子对铜绿微囊藻生长和藻毒素释放的
              ［  6  ］   Duy T N, Lam P K, Shaw G R, et al. Toxicology and  影响  [D]. 合肥：合肥工业大学，2022.
                   risk assessment of freshwater cyanobacterial (blue-green  Wang Z. Effects of copper and zinc ions on Microcystis
                   algal)  toxins  in  water[J].  Reviews  of  Environmental  aeruginosa  growth  and  microcystis  toxin  release[D].
                   Contamination and Toxicology, 2000, 163: 113 − 185.  Hefei: Hefei University of Technology, 2022.
              ［  7  ］   Schreidah C M, Ratnayake K, Senarath K, et al. Micro-  ［17］   贾惠雁，陈永华，陈明利，等. 5  种水生植物对铜绿
                   cystins:  biogenesis,  toxicity,  analysis,  and  control[J].  微囊藻的抑制与生理影响研究  [J]. 农业现代化研
                   Chemical Research in Toxicology, 2020, 33(9): 2225 −  究，2019，40（6） ：1056 − 1064.
                   2246.                                            Jia H Y, Chen Y H, Chen M L, et al. Allelopathic effect
              ［  8  ］   Roy S, Guljamow A, Dittmann E. Impact of temperature  of  five  aquatic  plants  on  Microcystis  aeruginosa[J].
                   on the temporal dynamics of microcystin in Microcystis  Research  of  Agricultural  Modernization,  2019,  40(6):
                   aeruginosa  PCC7806[J].  Frontiers  in  Microbiology,  1056 − 1064.
                   2023, 14: 1200816.                         ［18］   Zamora-Barrios C A, Nandini S, Sarma S S S. Bioaccu-
              ［  9  ］   Tito J C R, Luna L M G, Noppe W N, et al. First report  mulation of microcystins in seston, zooplankton and fish:

                   on  microcystin-LR  occurrence  in  water  reservoirs  of  a  case  study  in  Lake  Zumpango,  Mexico[J].  Environ-
                   eastern cuba, and environmental trigger factors[J]. Tox-  mental Pollution, 2019, 249: 267 − 276.
                   ins, 2022, 14(3): 209.                     ［19］   Chia M A, Kramer B J, Jankowiak J G, et al. The indi-
              ［10］   徐杜敏. 巢湖微囊藻毒素分布特征及影响机制的研究                       vidual and combined effects of the cyanotoxins, anatox-
                   [D]. 合肥：安徽建筑大学，2022.                             in-a  and  microcystin-LR, on  the  growth,  toxin   produc-
                   Xu  D  M.  Mechanism  of  microcystins  in  Chaohu  Lake  tion, and nitrogen fixation of prokaryotic and eukaryotic
                   study  on  distribution  characteristics  and  influence[D].  algae[J]. Toxins, 2019, 11(1): 43.
                   Hefei: Anhui Jianzhu University, 2022.     ［20］   许秋瑾，高光，陈伟民. 太湖微囊藻毒素年变化及其
              ［11］   Fernández-Juárez V, Bennasar-Figueras A, Sureda-Gom-  与 浮 游 生 物 的 关 系  [J].  中 国 环 境 科 学 ， 2005，
                   ila A, et al. Differential effects of varying concentrations  25（1） ：28 − 31.
                   of phosphorus, iron, and nitrogen in N 2 -fixing Cyanobac-  Xu Q J, Gao G, Chen W M. Periodical change of micro-
                   teria[J]. Frontiers in Microbiology, 2020, 11: 541558.  cystin in Taihu Lake and its relationship with plankton
              ［12］   Xiao M, Burford M A, Wood S A, et al. Schindler’s leg-  [J]. China Environmental Science, 2005, 25(1): 28 − 31.
                   acy:  from  eutrophic  lakes  to  the  phosphorus  utilization  ［21］   Krztoń W, Pudaś K, Pociecha A, et al. Microcystins af-
                   strategies of Cyanobacteria[J]. FEMS Microbiology Re-  fect zooplankton biodiversity in oxbow lakes[J]. Envir-
                   views, 2022, 46(6): fuac029.                     onmental Toxicology and Chemistry, 2017, 36(1): 165 −
              ［13］   Zhang  Q,  Chen  Y  C,  Wang  M,  et  al.  Molecular  re-  174.
                   sponses to inorganic and organic phosphorus sources in  ［22］   Cianci-Gaskill J A, Knott K K, O' Hearn R, et al. Micro-
                   the  growth  and  toxin  formation  of  Microcystis  aeru-  cystin  accumulation  in  sportfish  from  an  agricultural
                   ginosa[J]. Water Research, 2021, 196: 117048.    reservoir  differs  among  feeding  guild,  tissue  type,  and
              ［14］   Chen Q W, Wang M, Zhang J Y, et al. Physiological ef-  time  of  sampling[J].  Aquatic  Toxicology,  2022,  250:
                   fects of nitrate, ammonium, and urea on the growth and  106242.
                   microcystins  contamination  of  Microcystis  aeruginosa:  ［23］   Shahmohamadloo R S, Poirier D G, Ortiz Almirall X, et al.
                   implication for nitrogen mitigation[J]. Water Research,  Assessing  the  toxicity  of  cell-bound  microcystins  on
                   2019, 163: 114890.                               freshwater pelagic and benthic invertebrates[J]. Ecotox-
              ［15］   Baer M M, Godwin C M, Johengen T H. The effect of  icology and Environmental Safety, 2020, 188: 109945.
                   single  versus  dual  nutrient  decreases  on  phytoplankton  ［24］   Chen L, Giesy J P, Adamovsky O, et al. Challenges of