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滇池藻胆蛋白时空分布特征及其影响因素分析

刘平 魏薇 杨俊晖 李建文 左李美 孟睿 段平洲 焦立新

刘平,魏薇,杨俊晖,等.滇池藻胆蛋白时空分布特征及其影响因素分析[J].环境工程技术学报,2023,13(6):2174-2183 doi: 10.12153/j.issn.1674-991X.20230146
引用本文: 刘平,魏薇,杨俊晖,等.滇池藻胆蛋白时空分布特征及其影响因素分析[J].环境工程技术学报,2023,13(6):2174-2183 doi: 10.12153/j.issn.1674-991X.20230146
LIU P,WEI W,YANG J H,et al.Spatial and temporal distribution characteristics of phycobiliprotein in Dianchi Lake and analysis of its influencing factors[J].Journal of Environmental Engineering Technology,2023,13(6):2174-2183 doi: 10.12153/j.issn.1674-991X.20230146
Citation: LIU P,WEI W,YANG J H,et al.Spatial and temporal distribution characteristics of phycobiliprotein in Dianchi Lake and analysis of its influencing factors[J].Journal of Environmental Engineering Technology,2023,13(6):2174-2183 doi: 10.12153/j.issn.1674-991X.20230146

滇池藻胆蛋白时空分布特征及其影响因素分析

doi: 10.12153/j.issn.1674-991X.20230146
基金项目: 国家重点研发计划项目(2017YFA0605202,2021YFC3201003);国家科技基础性工作专项重点项目(2015FY110900);中央级公益性科研院所基本科研业务费专项(YSKY2023-10)
详细信息
    作者简介:

    刘平(1990—),男,工程师,主要从事滇池流域水环境监测及分析研究,1158159563@qq.com

    通讯作者:

    段平洲(1990—),男,副研究员,博士,主要从事水环境化学和污染控制技术研究,duanpz@craes.org.cn

  • 中图分类号: X524;X705

Spatial and temporal distribution characteristics of phycobiliprotein in Dianchi Lake and analysis of its influencing factors

  • 摘要:

    藻胆蛋白具有重要的经济价值,可以从藻体中提取、加工,从而实现藻泥废物的减量化与资源化。为厘清滇池水体藻胆蛋白的时空分布特征及其影响因素,于2022年不同季节进行了4次采样,在建立藻胆蛋白检测方法的基础上,分析了滇池草海、外海北部、外海中部和外海南部4个区域的藻胆蛋白时空变化特征,并基于ArcGIS建立了藻胆蛋白浓度时间和空间序列栅格数据图。结果表明:1)滇池藻胆蛋白浓度在时间上呈现夏季>秋季>春季>冬季的分布特征,在空间上呈现外海北部>外海中部>外海南部>草海的规律,且以藻蓝蛋白为主要成分,藻红蛋白的浓度较低。2)通过对各影响因子的统计分析发现,藻蓝蛋白浓度与TP浓度和BOD5存在显著的线性相关性(P<0.01),藻红蛋白浓度与营养盐的相关性较低,藻胆蛋白浓度与pH、DO浓度和透明度的线性关系显著(P<0.05)。3)对藻胆蛋白的影响因子进行分湖区讨论,结果表明氮、磷是藻胆蛋白分布的主要驱动因子,并可能受到水力条件和藻类种群类别的影响。4)草海虽然具有最高的TN、TP平均浓度,但其氮磷比(N/P)过高,蓝藻群落被绿藻取代,导致其藻胆蛋白浓度最低;外海北部具有较长的水力停留时间和较低的N/P,造成蓝藻种群占比高,藻胆蛋白的浓度最高;滇池水体春冬季的N/P显著高于夏秋季,这也是夏秋季藻胆蛋白浓度高于春冬季的主要原因之一。

     

  • 图  1  滇池流域水系和采样点分布

    Figure  1.  Water system of Dianchi Lake Basin and distribution of sampling points

    图  2  藻胆蛋白的吸光波谱和标准曲线

    注:C为藻胆蛋白浓度;A为吸光度。

    Figure  2.  Absorption spectrum and standard curve of phycobiliprotein

    图  3  滇池藻红蛋白浓度时空分布

    Figure  3.  Spatial and temporal distribution of phycoerythrin concentration in Dianchi Lake

    图  4  滇池藻蓝蛋白浓度时空分布

    Figure  4.  Spatial and temporal distribution of phycocyanin concentration in Dianchi Lake

    图  5  滇池藻类组分与环境因子相关性分析

    Figure  5.  Correlation analysis of algae components and environmental factors in Dianchi Lake

    图  6  2022年滇池水体TN、TP浓度和N/P月度变化

    Figure  6.  Monthly variation of TN, TP concentrations and N/P in Dianchi Lake in 2022

    表  1  滇池不同湖区水体TN、TP浓度与藻胆蛋白浓度皮尔逊相关系数

    Table  1.   Pearson correlation coefficient between TN, TP and phycobiliprotein concentrations in different lakes of Dianchi Lake

    湖区指标TPTNN/P藻红蛋白藻蓝蛋白
    草海TP10.079−0.613**0.1660.373*
    TN10.357*−0.115−0.152
    N/P1−0.169−0.373*
    藻红蛋白10.371
    藻蓝蛋白1
    外海北部TP10.436*0.671**0.382*0.604**
    TN10.442*−0.321*−0.396*
    N/P1−0.167−0.489*
    藻红蛋白10.424*
    藻蓝蛋白1
    外海中部TP1−0.664**−0.713**0.493*0.637**
    TN10.397*−0.2990.404*
    N/P1−0.198−0.449*
    藻红蛋白10.392*
    藻蓝蛋白1
    外海南部TP1−0.487*−0.498**0.2790.411*
    TN10.266−0.213−0.374
    N/P1−0.179−0.406*
    藻红蛋白10.383*
    藻蓝蛋白1
      注:*表示P<0.05,**表示P<0.01。
    下载: 导出CSV
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  • 收稿日期:  2023-02-23
  • 网络出版日期:  2023-11-24

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