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大洋桥石藻Gephyrocapsa oceanica对海水酸化与营养盐胁迫的复合响应

蔡小霞 于培松 张海峰 胡佶 张海娜 潘建明

蔡小霞, 于培松, 张海峰, 胡佶, 张海娜, 潘建明. 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. doi: 10.3969/j.issn.0253-4193.2016.04.012
引用本文: 蔡小霞, 于培松, 张海峰, 胡佶, 张海娜, 潘建明. 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. doi: 10.3969/j.issn.0253-4193.2016.04.012
Cai Xiaoxia, Yu Peisong, Zhang Haifeng, Hu Ji, Zhang Haina, Pan Jianming. Combined effects of seawater acidification and nitrogen deficiency on Gephyrocapsa oceanica[J]. Haiyang Xuebao, 2016, 38(4): 130-138. doi: 10.3969/j.issn.0253-4193.2016.04.012
Citation: Cai Xiaoxia, Yu Peisong, Zhang Haifeng, Hu Ji, Zhang Haina, Pan Jianming. Combined effects of seawater acidification and nitrogen deficiency on Gephyrocapsa oceanica[J]. Haiyang Xuebao, 2016, 38(4): 130-138. doi: 10.3969/j.issn.0253-4193.2016.04.012

大洋桥石藻Gephyrocapsa oceanica对海水酸化与营养盐胁迫的复合响应

doi: 10.3969/j.issn.0253-4193.2016.04.012
基金项目: 国家海洋局第二海洋研究所基本科研业务费专项资助(JG1406);国家海洋局全球变化与海气相互作用专项(GASI-03-01-03-02);浙江省自然科学基金(LY14D060008)。

Combined effects of seawater acidification and nitrogen deficiency on Gephyrocapsa oceanica

  • 摘要: 本文选取了大洋桥石藻(Gephyrocapsa oceanica)作为实验对象,通过CO2加富实验模拟海水酸化环境,分析了氮充足和氮相对不足条件下海洋颗石藻对海水酸化的生理响应。结果发现在两种营养盐状态下,CO2加富均能一定程度促进大洋桥石藻种群增长与Chl a浓度的增加。对比两种营养盐状态,氮相对不足条件下的大洋桥石藻细胞密度和叶绿素含量均有最显著的提高,表明低营养盐浓度和低的氮磷比可能更有利于大洋桥石藻的生长繁殖。电镜观测结果显示酸化对大洋桥石藻的钙化作用具有显著的负影响,并且在氮相对不足条件下,大洋桥石藻的细胞个体变小及比表面积升高。研究结果表明在未来寡营养的大洋上层水体,大气CO2浓度升高会对大洋桥石藻的生理功能产生负面影响,但可能刺激大洋桥石藻的生长。
  • Quay P D,Tibrook B,Wong C S. Oceanic uptake of fossil fuel CO2:carbon13 evidence[J]. Science,1992,256(5053):74-79.
    Orr J C,Fabry V J,Aumont O,et al. Anthropogenic ocean acidification over the twenty-first century and its impact on calcifying organisms[J]. Nature,2005,437(7059):681-686.
    Doney S C,Fabry V J,Feely R A,et al. Ocean Acidification:the other CO2 problem[J]. Annu Rev Mar Sci,2009,1:169-192.
    Caldeira K,Wickett M E. Oceanography:anthropogenic carbon and ocean pH[J]. Nature,2003,425(6956):365,doi: 10.1038/425365a.
    Raven J A. Ocean acidification due to increasing atmospheric carbon dioxide[M]. London,UK:Royal Society,2005.
    Feely R A,Sabine C L,Lee K,et al. Impact of anthropogenic CO2 on the CaCO3 system in the oceans[J]. Science,2004,305(5682):362-366.
    Zondervan I,Zeebe R E,Rost B,et al. Decreasing marine biogenic calcification:a negative feedback on rising atmospheric pCO2[J]. Global Biogeochemical Cycles,2001,15(2):507-516.
    Rochelle-Newall E,Delille B,Frankignoulle M,et al. Chromophoric dissolved organic matter in experimental mesocosms maintained under different pCO2 levels[J]. Marine Ecology Progress Series,2004,272:25-31.
    阮祚禧. 海洋酸化对钙化浮游植物颗石藻的影响[D]. 汕头:汕头大学,2008. Ruan Zuoxi. Effects of ocean acidification on the calcifying phytoplankton coccolithophore[D]. Shantou:Shantou University,2008.
    Riebesell U,Zondervan I,Rost B,et al. Reduced calcification of marine plankton in response to increased atmospheric CO2[J]. Nature,2000,407(6802):364-367.
    Rost B,Riebesell U,Burkhardt S,et al. Carbon acquisition of bloom-forming marine phytoplankton[J]. Limnol Oceanogr,2003,48(1):55-67.
    蔡小霞,潘建明,张海娜,等. CO2加富对颗石藻Emiliania huxleyi生长及钙化作用的影响[J]. 海洋环境科学,2013,32(2):249-253. Cai Xiaoxia,Pan Jianming,Zhang Haina,et al. Effects of elevated CO2 concentration on growth and calcification of the coccolithes Emiliania huxleyi[J]. Marine Environmental Science,2013,32(2):249-253.
    Raven J A,Crawfurd K. Environmental controls on coccolithophore calcification[J]. Marine Ecology Progress Series,2012,470:137-166.
    Feng Y,Warner M E,Zhang Y,et al. Interactive effects of increased pCO2,temperature and irradiance on the marine coccolithophore Emiliania huxleyi(Prymnesiophyceae)[J]. European Journal of Phycology,2008,43(1):87-98.
    夏建荣,高坤山. 高浓度CO2对极大螺旋藻生长和光合作用的影响[J]. 水生生物学报,2001,25(5):474-480. Xia Jianrong,Gao Kunshan. Effects of high CO2 concentration on growth and photosynthesis of Spirulina maxima[J]. Acta Hydrobiologica Sinica,2001,25(5):474-480.
    夏建荣,高坤山. CO2浓度升高对斜生栅藻生长和光合作用的影响[J]. 植物生理学通讯,2002,38(5):431-433. Xia Jianrong,Gao Kunshan. Effect of elevated CO2 concentration on growth and photosynthesis of Scenedesmus obliquus[J]. Plant Physiology Communications,2002,38(5):431-433.
    夏建荣. 大气CO2浓度升高对海洋浮游植物影响的研究进展[J]. 湛江海洋大学学报,2006,26(3):106-110. Xia Jianrong. Advances in the study of the effects of elevaed atmospheric CO2 concentrations on marine phytoplankton[J]. Journal of Zhanjiang Ocean University,2006,26(3):106-110.
    邹定辉,高坤山. 高CO2浓度对大型海藻光合作用及有关过程的影响[J]. 生态学报,2002,22(10):1750-1757. Zou Dinghui,Gao Kunshan. Effects of elevated CO2 concentration on the photosynthesis and related physiological processes in marine macroalgae[J]. Acta Ecologica Sinica,2002,22(10):1750-1757.
    徐智广,邹定辉,张鑫,等. CO2和硝氮加富对龙须菜(Gracilaria lemaneiformis)生长、生化组分和营养盐吸收的影响[J]. 生态学报,2008,28(8):3752-3759. Xu Zhiguang,Zou Dinghui,Zhang Xin,et al. Effects of increased atmospheric CO2 and N supply on growth,biochemical compositions and uptake of nutrients in Gracilaria lemaneiformis(Rhodophyta)[J]. Acta Ecologica Sinica,2008,28(8):3752-3759.
    Falkowski P G. Evolution of the nitrogen cycle and its influence on the biological sequestration of CO2 in the ocean[J]. Nature,1997,387(3872):272-275.<扢敲琾睛攲攱湝?琋框攬?擘榚玉猬漘氈瘐攮搠?槺溿澸犮枋慅滻楛捍?挮愠爗抬漺湷?揺潈渾挬攱渹琹爳愺琱椭漱渲‵愮渠摃?来牮潧眠瑚桨?牯慤瑩攬?楡湯?浙慡牨極湩攬?灩桵礠瑓潨灩汣慨湥歮瑧漮渠孎?嵮??偰牬潡据?剴?卮潩捣??潩湡摴???㈠どの???????????????扝爮?孂??嵪?呮畧爺灃楨湩?????坥敡杮攠牐??????匹琹攳愺搱礭?猲琵愮琼敢?挾桛氲漲牝漠烽梶祷氋氇??槏?懃??榶??晀氬甀潷爋攔獶捀攮渠捷攋?瓥狄愃湇獂椯敔渠琱猲?搶申爭椲渰朰?慛浓浝漮渠椗疬洺?懽猇珆槺浈椾氬愲琰椰漸渮?扎祡?瑩桯敮?乬?汔楥浣楨瑮敩摣?杬爠敓敵湰?慲汶杩慳??楮?卂敵汲敥湡慵猬瑆物畲浳?洠楉湮畳瑴畩浴??楥?孯?崠??健污慮湯瑧?偡桰票獹椬漠汓????????????????ど???扴牲?孴??嵮?丠楓浰敥牣?书????物潯睮湳氠敦敯????敥牡牮敯瑧瑲???????慵牲扶潥湹?摇楂漯硔椠搱攲?愶瘳愭椲氰愰户楛汓楝琮礠?楥湩瑪物慮捧攺汃汨畩汮慥牳?瀠??慡湮摤?杲牤漠睐瑲桥?牳愬琲攰‰漸昮?瑢桲放?挲漳捝挠潈泄榇琬棘潤灱栮漠牃敏??極??洲椼氯楳慵湢椾慓?棹甭碋沨敡移榄??槠?害?崶???憳牸??挻漧沄?働牛潊杝?匠旑牦??????????㈨???呼?有??戭爲?嬷??崠??敥慮爠摘慩汯汮????爬楇晡景椠瑋桵獮???剮愮瘠故湦???????慦爠扃潏渼?極獢漾琲漼瀯敳?摢椾猠捣牯楮浣楥湮慴瑲楡潴湩?慮渠摯?琠桴敨??佰?獯畴扯????獨略扴??愠捩据畯浲畧污慮瑩楣渠杣?浲敢捯桮愠湵楰獴浡?楥渠??楤??桸汴潲牡散汥汬慬?敬浡敲爠獣潡湲楢楯??楣?孡?嵨?????硥瀠??潩瑶????㈠????????????????扡爠?孯??嵡??敭氼椯汩氾敛????慃牨汩慮祥???婓潣湩摥敮牣癥愠湂???敥瑴?慮氬?‰到攳猬瀴漸渨猲攱?漺昲′瀷爵椭洲愲爷礹?瀼牢潲搾畛挲琴楝漠湐?慡湳摣?捥愠汅挮椠晁椠捴慲瑡楣潥湲?瑳潴?捤桹愠湯杦攠獴?潥映??楯?灧??楩??佣?獲畢扯?㈠??獴畡扫??摤畵牲楩湮杧?散硯灣散牯楬浩整湨琠慦汯?扭污潴潩浯獮?潡普?琠桰敨?捴潯捳捹潮汴楨瑥桳潩灳栠潩牮椠摴??椠??浣楣汯楬慩湴楨慯?桨畯硲汩敤礠椼??楃?季?嵯???汨潵扳愠汨??楬潥杹敩漼振桩放浛??礮??とべ???????????ひ????戹父?嬬??嵳??湰杬攮氩???娸漲渮搼敢牲瘾慛渲‵???敩牥瑬獳???敍琠?愮氠??呯整獯瑳楹湮杴?瑥桴敩?搠楣牨敡捲瑡?整晥晲敩捳瑴?潣晳??佦?獴畨扥????獣畯扬??捨潯湰捨敯湲瑩牤愠琼楩漾湅?潩湬?慡?扩污漠潨浵?潬晥?瑩格支?挾漨捐捲潹汭楮瑥桳潩灯桰潨特楣摥??椩??浸楰汯楳慥湤椠慴?栠略硬汥敶祡楴??椠??楮湣?浮整獲潡捴潩獯浮?攠硯灦攠牤楩浳敳湯瑬獶孥?崠???楲浧湡潮汩?传捣敡慲湢潯杮牛???????と????????????(5):715-719.
    Berry L,Taylor A R,Lucken U,et al. Calcification and inorganic carbon acquisition in coccolithophores[J]. Funct Plant Biol,2002,29(2/3):289-299.
    Zondervan I,Rost B,Riebesell U. Effect of CO2 concentration on the PIC/POC ratio in the coccolithophore Emiliania huxleyi grown under light-limiting conditions and different daylengths[J]. J Exp Mar Biol Ecol,2002,272(1):55-70.
    Paasche E,Brubak S,Skattebøl S,et al. Growth and calcification in the coccolithophorid Emiliania huxleyi(Haptophyceae) at low salinities[J]. Phycologia,1996,35(5):394-403.
    Buitenhuis E T,De Baar H J W,Veldhuis M J W. Photosynthesis and calcification by Emiliania huxleyi(Prymnesiophyceae) as a function of inorganic carbon species[J]. J Phycol,1999,35(5):949-959.
    Clark D R,Flynn K J. The relationship
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  • 收稿日期:  2015-07-21
  • 修回日期:  2016-01-09

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