Analysis of environmental drivers influencing interspecific variations and associations among bloom-forming cyanobacteria in large, shallow eutrophic lakes.
暂无分享,去创建一个
Wei Chen | Liming Liu | Yanlong Wu | Lirong Song | Qichao Zhou | Lirong Song | Wei Chen | Liming Liu | Lin Li | K. Shan | Qichao Zhou | Yanlong Wu | Yunlu Jia | Liang Peng | Kun Shan | Lin Li | Yunlu Jia | Liang Peng | Kun Shan | Qichao Zhou
[1] Lirong Song,et al. Growth inhibitory effect of Microcystis on Aphanizomenon flos-aquae isolated from cyanobacteria bloom in Lake Dianchi, China , 2015 .
[2] J. Elser. The pathway to noxious cyanobacteria blooms in lakes : the food web as the final turn , 1999 .
[3] J. Berry,et al. Cyanobacterial Toxins as Allelochemicals with Potential Applications as Algaecides, Herbicides and Insecticides , 2008, Marine drugs.
[4] C. Gobler,et al. The effects of temperature and nutrients on the growth and dynamics of toxic and non-toxic strains of Microcystis during cyanobacteria blooms , 2009 .
[5] G. Pitcher,et al. Phylogenetic analysis of toxic Alexandrium (Dinophyceae) isolates from South Africa: implications for the global phylogeography of the Alexandrium tamarense species complex , 2005 .
[6] D. Schindler. The dilemma of controlling cultural eutrophication of lakes , 2012, Proceedings of the Royal Society B: Biological Sciences.
[7] K. O’Brien,et al. Variation within and between cyanobacterial species and strains affects competition: Implications for phytoplankton modelling. , 2017, Harmful algae.
[8] Anna-Kristina Brunberg. Microbial activity and phosphorus dynamics in eutrophic lake sediments enriched with Microcystis colonies , 1995 .
[9] S. Levin,et al. Optimal nitrogen-to-phosphorus stoichiometry of phytoplankton , 2004, Nature.
[10] H. Jensen,et al. Importance of temperature, nitrate, and pH for phosphate release from aerobic sediments of four shallow, eutrophic lakes , 1992 .
[11] C. Steinberg,et al. Planktonic bloom-forming Cyanobacteria and the eutrophication of lakes and rivers , 1988 .
[12] H. Paerl,et al. Effects of inorganic nitrogen on taxa‐specific cyanobacterial growth and nifH expression in a subtropical estuary , 2008 .
[13] H. Paerl,et al. Climate change: a catalyst for global expansion of harmful cyanobacterial blooms. , 2009, Environmental microbiology reports.
[14] P. Leavitt,et al. Comparative effects of urea, ammonium, and nitrate on phytoplankton abundance, community composition, and toxicity in hypereutrophic freshwaters , 2011 .
[15] Samuel M. Scheiner,et al. On the specification of structural equation models for ecological systems. , 2010 .
[16] Alan E. Wilson,et al. Effects of cyanobacterial toxicity and morphology on the population growth of freshwater zooplankton: Meta‐analyses of laboratory experiments , 2006 .
[17] Shengjun Wu,et al. Greenhouse gas emissions from riparian zone cropland in a tributary bay of the Three Gorges Reservoir, China , 2020, PeerJ.
[18] Yves Rosseel,et al. lavaan: An R Package for Structural Equation Modeling , 2012 .
[19] Lirong Song,et al. Patterns of succession between bloom-forming cyanobacteria Aphanizomenon flos-aquae and Microcystis and related environmental factors in large, shallow Dianchi Lake, China , 2015, Hydrobiologia.
[20] R. Zurawell,et al. Predicting cyanobacterial dynamics in the face of global change: the importance of scale and environmental context , 2012 .
[21] M. Pagano,et al. Can tropical freshwater zooplankton graze efficiently on cyanobacteria? , 2011, Hydrobiologia.
[22] M. Pace,et al. Bloom formation in heterocystic nitrogen‐fixing cyanobacteria: The dependence on colony size and zooplankton grazing , 2004 .
[23] B. Byrne. Structural equation modeling with EQS : basic concepts, applications, and programming , 2000 .
[24] Raphael M Kudela,et al. Harmful algal blooms and climate change: Learning from the past and present to forecast the future. , 2015, Harmful algae.
[25] Justin D. Brookes,et al. The interaction between climate warming and eutrophication to promote cyanobacteria is dependent on trophic state and varies among taxa , 2014 .
[26] David P. Hamilton,et al. Eco-physiological adaptations that favour freshwater cyanobacteria in a changing climate. , 2012, Water research.
[27] Lin Jiang,et al. Temperature fluctuation facilitates coexistence of competing species in experimental microbial communities. , 2007, The Journal of animal ecology.
[28] Helmut Hillebrand,et al. Nutrient co-limitation of primary producer communities. , 2011, Ecology letters.
[29] David W. Schindler,et al. Eutrophication of lakes cannot be controlled by reducing nitrogen input: Results of a 37-year whole-ecosystem experiment , 2008, Proceedings of the National Academy of Sciences.
[30] S. Azevedo,et al. Effect of grazing by a neotropical copepod, Notodiaptomus, on a natural cyanobacterial assemblage and on toxic and non-toxic cyanobacterial strains , 2003 .
[31] O. Anneville,et al. Are cyanobacterial blooms trophic dead ends? , 2012, Oecologia.
[32] K. McMahon,et al. Spatiotemporal Molecular Analysis of Cyanobacteria Blooms Reveals Microcystis - Aphanizomenon Interactions , 2013, PloS one.
[33] A. Bailey‐Watts,et al. Vertical movements by planktonic cyanobacteria and the translocation of phosphorus: implications for lake restoration , 1999 .
[34] B. Böddi,et al. Chlorophyll-a determination with ethanol – a critical test , 2002, Hydrobiologia.
[35] Lirong Song,et al. Multi-Year Assessment of Toxic Genotypes and Microcystin Concentration in Northern Lake Taihu, China , 2016, Toxins.
[36] J. Downing,et al. Predicting cyanobacteria dominance in lakes , 2001 .
[37] Shinichi Nakagawa,et al. A general and simple method for obtaining R2 from generalized linear mixed‐effects models , 2013 .
[38] Hiroyuki Nakahara,et al. Seasonal succession of phytoplankton in Lake Yogo over 2 years: effect of artificial manipulation , 2006, Limnology.
[39] David P. Hamilton,et al. Determining the probability of cyanobacterial blooms: the application of Bayesian networks in multiple lake systems. , 2015, Ecological applications : a publication of the Ecological Society of America.
[40] C. Gobler,et al. The rise of harmful cyanobacteria blooms: The potential roles of eutrophication and climate change , 2012 .
[41] Lirong Song,et al. Modelling ecosystem structure and trophic interactions in a typical cyanobacterial bloom-dominated shallow Lake Dianchi, China , 2014 .
[42] H. Paerl,et al. Nitrogen and phosphorus inputs control phytoplankton growth in eutrophic Lake Taihu, China , 2010 .
[43] M. Scheffer,et al. Warmer climates boost cyanobacterial dominance in shallow lakes , 2012 .
[44] M. Dokulil,et al. Cyanobacterial dominance in lakes , 2000, Hydrobiologia.
[45] Marti J. Anderson,et al. Partitioning the variation among spatial, temporal and environmental components in a multivariate data set , 1998 .
[46] Effects of nutrient availability and temperature on phytoplankton development: a case study from large lakes south of the Alps , 2012, Aquatic Sciences.
[47] Irene Gregory-Eaves,et al. Nutrients and water temperature are significant predictors of cyanobacterial biomass in a 1147 lakes data set , 2013 .
[48] H. Paerl,et al. Spatiotemporal patterns and ecophysiology of toxigenic microcystis blooms in Lake Taihu, China: implications for water quality management. , 2012, Environmental science & technology.
[49] Kenneth A. Bollen,et al. Representing general theoretical concepts in structural equation models: the role of composite variables , 2008, Environmental and Ecological Statistics.
[50] Min Zhang,et al. Spatial and seasonal shifts in bloom‐forming cyanobacteria in Lake Chaohu: Patterns and driving factors , 2016 .
[51] D. Schindler,et al. Eutrophication science: where do we go from here? , 2009, Trends in ecology & evolution.
[52] P. Reich,et al. Phosphorus accumulates faster than nitrogen globally in freshwater ecosystems under anthropogenic impacts. , 2016, Ecology letters.
[53] Guangwei Zhu,et al. Controlling Cyanobacterial Blooms in Hypertrophic Lake Taihu, China: Will Nitrogen Reductions Cause Replacement of Non-N2 Fixing by N2 Fixing Taxa? , 2014, PloS one.
[54] S. Azevedo,et al. Changes in species composition during annual cyanobacterial dominance in a tropical reservoir: physical factors, nutrients and grazing effects , 2009 .
[55] J. Hopcraft,et al. Body size and the division of niche space: food and predation differentially shape the distribution of Serengeti grazers. , 2012, The Journal of animal ecology.
[56] P. Legendre,et al. Partialling out the spatial component of ecological variation , 1992 .
[57] Wayne S Gardner,et al. Nitrogen dynamics and microbial food web structure during a summer cyanobacterial bloom in a subtropical, shallow, well-mixed, eutrophic lake (Lake Taihu, China) , 2007, Hydrobiologia.
[58] M. Pace,et al. Ecological and Biogeochemical Interactions Constrain Planktonic Nitrogen Fixation in Estuaries , 2002, Ecosystems.
[59] H. Paerl,et al. Climate change: links to global expansion of harmful cyanobacteria. , 2012, Water research.
[60] P. Nyvall,et al. Regulation of non-nitrogen-fixing cyanobacteria by inorganic nitrogen sources-experiments from Lake Erken , 1998 .
[61] Miquel Lürling,et al. Understanding cyanobacteria‐zooplankton interactions in a more eutrophic world , 2014 .
[62] K. Weathers,et al. Cyanobacteria as biological drivers of lake nitrogen and phosphorus cycling , 2015 .
[63] B. Xiao,et al. Seasonal dynamics of water bloom-forming Microcystis morphospecies and the associated extracellular microcystin concentrations in large, shallow, eutrophic Dianchi Lake. , 2014, Journal of environmental sciences.
[64] H. Paerl,et al. Duelling 'CyanoHABs': unravelling the environmental drivers controlling dominance and succession among diazotrophic and non-N2 -fixing harmful cyanobacteria. , 2016, Environmental microbiology.
[65] R. Adrian,et al. Cyanobacteria dominance: Quantifying the effects of climate change , 2009 .