全部 标题 作者
关键词 摘要

OALib Journal期刊
ISSN: 2333-9721
费用:99美元
投递稿件

查看量下载量

相关文章

更多...

硝磺草酮对微囊藻和四尾栅藻光合作用及竞争的影响

DOI: 10.11654/jaes.2014.12.022, PP. 2436-2443

Keywords: 硝磺草酮,竞争,光合作用,四尾栅藻,微囊藻

Full-Text   Cite this paper   Add to My Lib

Abstract:

采用纯培养和混合培养方法,结合调制叶绿素荧光测定技术,研究了硝磺草酮对微囊藻和四尾栅藻光合作用及种间竞争的影响.结果表明:0.5~10mg·L-1硝磺草酮降低了微囊藻和四尾栅藻的最大光化学量子产量(Fv/Fm)和快速光曲线(RLCs)拟合参数(Ik、α、ETRmax),降低幅度与硝磺草酮浓度正相关;处理14d时,Fv/Fm、Ik、α、ETRmax水平均达到暴露以来最小值,表明微囊藻和四尾栅藻在硝磺草酮处理期间未表现出恢复趋势.对比2种藻荧光参数变幅可知,硝磺草酮对四尾栅藻各荧光参数影响大于微囊藻,表明四尾栅藻的敏感性高于微囊藻.混合培养实验结果显示对照组微囊藻同四尾栅藻相比处于竞争劣势,而5、10mg·L-1硝磺草酮处理时,微囊藻在与四尾栅藻的种间竞争中逐渐占据优势,且在微囊藻与四尾栅藻初始接种体积比为1:3的混合培养体系中表现出最强的竞争力.较高浓度的硝磺草酮可使微囊藻由原劣势地位转为逐渐占据竞争优势,故硝磺草酮对水体中蓝藻水华的爆发具有潜在的促进作用.

 References

[1]  Conley D J, Paerl H W, Howarth R W, et al. Controlling eutrophication:Nitrogen and phosphorus[J]. Science, 2009, 323(5917):1014-1015.
[2]  Smith V H, Schindler D W. Eutrophication science:Where do we go from here?[J]. Trends in Ecology & Evolution, 2009, 24(4):201-207.
[3]  孔繁翔, 高 光. 大型浅水富营养化湖泊中蓝藻水华形成机理的思考[J]. 生态学报, 2005, 25(3):589-595. KONG Fan-xiang, GAO Guang. Hypothesis on cyanobacteria bloom-forming mechanism in large shallow eutrophic lakes[J]. Acta Ecologica Sinica, 2005, 25(3):589-595.
[4]  Zeng J, Wang W X. Temperature and irradiance influences on cadmium and zinc uptake and toxicity in a freshwater cyanobacterium, Microcystis aeruginosa[J]. Journal of Hazardous Materials, 2011, 190(1):922-929.
[5]  Lürling M, Roessink I. On the way to cyanobacterial blooms:Impact of the herbicide metribuzin on the competition between a green alga(Scenedesmus) and a cyanobacterium(Microcystis)[J]. Chemosphere, 2006, 65(4):618-626.
[6]  Ma J. Differential sensitivity of three cyanobacterial and five green algal species to organotins and pyrethroids pesticides[J]. Science of the Total Environment, 2005, 341(1):109-117.
[7]  Brock T, Crum S J H, Deneer J W, et al. Comparing aquatic risk assessment methods for the photosynthesis-inhibiting herbicides metribuzin and metamitron[J]. Environmental Pollution, 2004, 130(3):403-426.
[8]  Prado R, Rioboo C, Herrero C, et al. The herbicide paraquat induces alterations in the elemental and biochemical composition of non-target microalgal species[J]. Chemosphere, 2009, 76(10):1440-1444.
[9]  Hela D G, Lambropoulou D A, Konstantinou I K, et al. Environmental monitoring and ecological risk assessment for pesticide contamination and effects in Lake Pamvotis, Northwestern Greece[J]. Environmental Toxicology and Chemistry, 2005, 24(6):1548-1556.
[10]  Mitchell G, Bartlett D W, Fraser T E M, et al. Mesotrione:A new selective herbicide for use in maize[J]. Pest Management Science, 2001, 57(2):120-128.
[11]  Ter Halle A, Richard C. Simulated solar light irradiation of mesotrione in natural waters[J]. Environmental Science & Technology, 2006, 40(12):3842-3847.
[12]  Abou-Waly H, Abou-Setta M M, Nigg H N, et al. Growth response of freshwater algae, Anabaena flos-aquae and Selenastrum capricornutum to atrazine and hexazinone herbicides[J]. Bulletin of Environmental Contamination and Toxicology, 1991, 46(2):223-229.
[13]  McCurdy J D, McElroy J S, Kopsell D A, et al. Effects of mesotrione on perennial ryegrass(Lolium perenne L.) carotenoid concentrations under varying environmental conditions[J]. Journal of Agricultural and Food Chemistry, 2008, 56(19):9133-9139.
[14]  Bonnet J L, Bonnemoy F, Dusser M, et al. Toxicity assessment of the herbicides sulcotrione and mesotrione toward two reference environmental Microorganisms:Tetrahymena pyriformis and Vibrio fischeri[J]. Archives of Environmental Contamination and Toxicology, 2008, 55(4):576-583.
[15]  Czyczylo-Mysza I, Tyrka M, Marcińska I, et al. Quantitative trait loci for leaf chlorophyll fluorescence parameters, chlorophyll and carot-enoid contents in relation to biomass and yield in bread wheat and their chromosome deletion bin assignments[J]. Molecular Breeding, 2013, 32(1):189-210.
[16]  Schreiber U, Schliwa U, Bilger W. Continuous recording of photochemical and non-photochemical chlorophyll fluorescence quenching with a new type of modulation fluorometer[J]. Photosynthesis Research, 1986, 10(1-2):51-62.
[17]  Herlory O, Bonzom J M, Gilbin R. Sensitivity evaluation of the green alga Chlamydomonas reinhardtii to uranium by pulse amplitude modulated(PAM) fluorometry[J]. Aquatic Toxicology, 2013, 140:288-294.
[18]  Ni Y, Lai J H, Wan J B, et al. Photosynthetic responses and accumulation of mesotrione in two freshwater algae[J]. Environmental Science Processes & Impacts, 2014, 16(10): 2288-2294.
[19]  Kim D G, La H J, Ahn C Y, et al. Harvest of Scenedesmus sp. with bioflocculant and reuse of culture medium for subsequent high-density cultures[J]. Bioresource Technology, 2011, 102(3):3163-3168.
[20]  Rippka R, Deruelles J, Waterbury J B, et al. Generic assignments, strain histories and properties of pure cultures of cyanobacteria[J]. Journal of General Microbiology, 1979, 111(1):1-61.
[21]  Korner S, Nicklisch A. Allelopathic growth inhibition of selected phytoplankton species by submerged macrophytes[J]. Journal of Phycology, 2002, 38(5):862-871.
[22]  Schreiber U, Bilger W. Progress in chlorophyll fluorescence research:Major developments during the past years in retrospect[J]. Progress in Botany, 1993, 54:151-173.
[23]  Jakob T, Schreiber U, Kirchesch V, et al. Estimation of chlorophyll content and daily primary production of the major algal groups by means of multiwavelength-excitation PAM chlorophyll fluorometry:Performance and methodological limits[J]. Photosynthesis Research, 2005, 83(3):343-361.
[24]  陈德辉, 刘永定, 袁峻峰, 等. 微囊藻和栅藻共培养实验及其竞争参数的计算[J]. 生态学报, 1999, 19(6):908-913. CHEN De-hui, LIU Yong-ding, YUAN Jun-feng, et al. Experiments of mixed culture and calculation of competitive parameters between Microcystis(Cyanobacteria) and Scenedesmus(Green algae)[J]. Acta Ecologica Sinica, 1999, 19(6):908-913.
[25]  Volterra V. Fluctuations in the abundance of a species considered mathematically[J]. Nature, 1926, 118:558-560.
[26]  Sjollema S B, van Beusekom S A M, van der Geest H G, et al. Laboratory algal bioassays using PAM fluorometry:Effects of test conditions on the determination of herbicide and field sample toxicity[J]. Environmental Toxicology and Chemistry, 2014, 33(5):1017-1022.
[27]  Muller R, Schreiber U, Escher B I, et al. Rapid exposure assessment of PSII herbicides in surface water using a novel chlorophyll a fluorescence imaging assay[J]. Science of the Total Environment, 2008, 401(1):51-59.
[28]  Knauert S, Escher B, Singer H, et al. Mixture toxicity of three photosystem Ⅱ inhibitors(atrazine, isoproturon, and diuron) oward photosynthesis of freshwater phytoplankton studied in outdoor mesocosms[J]. Environmental Science & Technology, 2008, 42(17):6424-6430.
[29]  Navarro E, Piccapietra F, Wagner B, et al. Toxicity of silver nanoparticles to Chlamydomonas reinhardtii[J]. Environmental Science & Technology, 2008, 42(23):8959-8964.
[30]  McMinn A, Hegseth E N. Quantum yield and photosynthetic parameters of marine microalgae from the Southern Arctic Ocean, Svalbard[J]. Journal of the Marine Biological Association of the UK, 2004, 84(19):865-871.
[31]  Maxwell K, Johnson G N. Chlorophyll fluorescence-a practical guide[J]. Journal of Experimental Botany, 2000, 51(345):659-668.
[32]  Ralph P J, Gademann R. Rapid light curves:A powerful tool to assess photosynthetic activity[J]. Aquatic Botany, 2005, 82(3):222-237.
[33]  Serodio J, Vieira S, Cruz S, et al. Short-term variability in the photosynthetic activity of microphytobenthos as detected by measuring rapid light curves using variable fluorescence[J]. Marine Biology, 2005, 146(5):903-914.
[34]  Dewez D, Didur O, Vincent-Héroux J, et al. Validation of photosynthetic-fluorescence parameters as biomarkers for isoproturon toxic effect on alga Scenedesmus obliquus[J]. Environmental Pollution, 2008, 151(1):93-100.
[35]  Bi Y F, Miao S S, Lu Y C, et al. Phytotoxicity, bioaccumulation and degradation of isoproturon in green algae[J]. Journal of Hazardous Materials, 2012, 243:242-249.
[36]  Deblois C P, Dufresne K, Juneau P. Response to variable light intensity in photoacclimated algae and cyanobacteria exposed to atrazine[J]. Aquatic Toxicology, 2013, 126:77-84.
[37]  潘克厚, 王金凤, 朱葆华. 海洋微藻间竞争研究进展[J]. 海洋科学, 2007, 31(5):58-62. PAN Ke-hou, WANG Jin-feng, ZHU Bao-hua. Progress on study of competition among marine microalgae[J]. Marine Sciences, 2007, 31(5):58-62.
[38]  Keating K I. Blue-green algal inhibition of diatom growth:Transition from mesotrophic to eutrophic community structure[J]. Science, 1978, 199(4332):971-973.
[39]  Inderjit D K M M, Dakshini K M M. Algal allelopathy[J]. Botanical Review, 1994, 60(2):182-196.
[40]  Keating K I. Allelopathic influence on blue-green bloom sequence in a eutrophic lake[J]. Science, 1977, 196(4292):885-887.
[41]  Tameishi M, Yamasaki Y, Nagasoe S, et al. Allelopathic effects of the dinophyte Prorocentrum minimum on the growth of the bacillariophyte Skeletonema costatum[J]. Harmful Algae, 2009, 8(3):421-429.
[42]  Wang Y, Tang X. Interactions between Prorocentrum donghaiense Lu and Scrippsiella trochoidea(Stein) Loeblich Ⅲ under laboratory culture[J]. Harmful Algae, 2008, 7(1):65-75.
[43]  Armstrong R A. A hybrid spectral representation of phytoplankton growth and zooplankton response: The “control rod” model of plankton interaction[J]. Deep Sea Research Part Ⅱ:Topical Studies in Oceanography, 2003, 50(22):2895-2916.
[44]  Van der Westhuizen A J, Eloff J N. Effect of temperature and light on the toxicity and growth of the blue-green alga Microcystis aeruginosa(UV-006)[J]. Planta, 1985, 163(1):55-59.
[45]  孟顺龙, 裘丽萍, 胡庚东, 等. 氮磷比对两种蓝藻生长及竞争的影响[J]. 农业环境科学学报, 2012, 31(7):1438-1444. MENG Shun-long, QIU Li-ping, HU Geng-dong, et al. Effect of nitrogen and phosphorus ratios on growth and competition of two blue-green algae[J]. Journal of Agro-Environment Science, 2012, 31(7):1438-1444.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133