颗石藻光合作用与钙化作用的研究现状
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摘要
对颗石藻的生物学种类、形态特征、分布特点做了简单概括,探讨了影响颗石藻光合作用与钙化作用的多种因素,包括光照、温度、营养盐与海水酸化,揭示了光合作用与钙化作用之间的偶联机制,对颗石藻的利用价值做出了展望。
引文
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[18]Oviedo A M,Langer G,Ziveri P.Effect of phosphorus limitation on coccolith morphology and element ratios in Mediterranean strains of the coccolithophore Emiliania huxleyi[J].Journal of Experimental Marine Biology and Ecology,2014,459:105-113.
[19]张健,李佳芮,纪大伟,等.黄东海夏、冬季颗石藻群落及其分布研究[J].海洋科学,2016,40(2):41-54.
[20]Nanninga H J,Tyrrell T.Importance of light for the formation of algal blooms by Emiliania huxleyi[J].Marine Ecology Progress,1996,136(1-3):195-203.
[21]周成旭,严小军,骆其君,等.低温和高温下颗石藻(Pleurochrysis sp.)种群生长特征及生化变化[J].生态学报,2008,28(6):2587-2594.
[22]Wei K Y,Gong G C.Summer and Winter Distribution and Malformation of Coccolithophores in the East China Sea[J].Micropaleontology,2004,50(supplement No.1):157-170.
[23]孙军,安佰正,戴民汉,等.夏季南海西部今生颗石藻[J].海洋与湖沼,2011,42(2):170-178.
[24]林凌.日本南海海槽中更新世以来颗石藻组合及其意义[D].中国地质大学(北京),2012.
[25]栾青杉.夏冬季中国近海今生颗石藻及其钙化作用速率研究[D].中国科学院研究生院(海洋研究所),2010.
[26]Gerecht A C,Supraha L,Edvardsen B,et al.Phosphorus availability modifies carbon production in Coccolithus pelagicus,(Haptophyta)[J].Journal of Experimental Marine Biology and Ecology,2015,472(9):24-31.
[27]Ziveri P,Stoll H M,Probert I,et al.Stable isotope“vital effects”in coccolith calcite[J].Earth&Planetary Science Letters,2003,210(1):137-149.
[28]Hu Q,Sommerfeld M,Jarvis E,et al.Microalgal triacylglycerols as feedstocks for biofuel production:perspectives and advances[J].The Plant Journal,2010,54(4):621-639.
[29]Moheimani N R,Borowitzka M A.The long-term culture of the coccolithophore[J].Journal of Applied Phycology,2006,18:703-712.
[30]James B,Cotner J,Wetzel R G.Uptake of dissolved inorganic and organic bphosphorus compounds by phytoplankton and bacterioplankton[J].Limnology and Oceanography,1992,37(2):232-243.
[31]刘宝宁.富营养化条件下磷对颗石藻关键生理生态过程的作用及意义[D].宁波大学,2012.
[32]陈攀.颗石类微藻Pleurochrysis carterae培养条件的优化及室外培养研究[D].湖北工业大学,2013.
[33]Olson M B,Wuori T A,Love B A,et al.Ocean acidification effects on haploid and diploid Emiliania huxleyi,strains:Why changes in cell size matter[J].Journal of Experimental Marine Biology&Ecology,2017,488:72-82.
[34]Jeffrey S W,Wright S W.Photosynthetic pigments in the Haptophyta.(Cohen Z.)Chemicals from Microalgae[M].Taylor and Francis Philadelphia,1999,pp:111-132.
[35]吴庆余,白岩善博.HCO-3对海生颗石藻细胞表面钙化和CO2固定作用的研究[J].Journal of Integrative Plant Biology,1999(3):285-289.
[36]Gao K,高坤山.Ocean acidification exacerbates the effect of UV radiation on the calcifying phytoplankter Emiliania huxleyi[D].Amer Soc Limnology Oceanography,2009.
[37]阮祚禧,邹定辉,许振平,等.颗石球缓解紫外辐射对颗石藻光合作用的胁迫[J].水生生物学报,2016,40(5):1078-1082.
[38]Jdl V B,Mjw V.In situ gross growth rates of Emiliania huxleyi in enclosures with different phosphate loadings revealed by diel changes in DNA content[J].Marine Ecology Progress,1995,121(1):271-277.
[39]邢涛.钙化与硅化浮游植物的环境生理学研究[D].厦门大学,2016.
[40]Leonardos N,Geider R J.Elevated atmospheric carbon dioxide increases organic carbon fixation by Emiliania huxleyi,(Haptophyta),under nutrient-limited high-light conditions[J].Journal of Phycology,2010,41(6):1196-1203.
[41]Hu Q A,Richmond A.Environmental effects on cell composition.[M]//Handbook of Microalgal Culture:Applied Phycology and Biotechnology,Second Edition.John Wiley&Sons,Ltd,2003:83-94.
[42]Sorrosa J M,Satoh M,Shiraiwa Y.Low temperature stimulates cell enlargement and intracellular calcification of coccolithophorids[J].Marine Biotechnology,2005,7(2):128-133.
[43]赵艳芳.富营养化环境下的海洋微藻生理生化特性研究[D].中国科学院研究生院(海洋研究所),2008.
[44]蔡小霞,于培松,张海峰,等.大洋桥石藻Gephyrocapsa oceanica对海水酸化与营养盐胁迫的复合响应[J].海洋学报,2016,38(4):130-138.
[45]孙军,刘海娇,李欣,等.南海北部夏、冬季今生颗石藻分布[J].海洋学报,2015,37(12):1-10.
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