Articles citing this paper
Advances in understanding how aquatic photosynthetic organisms utilize sources of dissolved inorganic carbon for CO2 fixation
G. Dean Price and Murray R. Badger
29(3) pp.117 - 121
21 articles found in Crossref database.
The Physiology of Characean Cells (2014)
Thirty Years of Photosynthesis 1974–2004 (2006)
Dynamic Changes in the Proteome of Synechocystis 6803 in Response to CO2 Limitation Revealed by Quantitative Proteomics
Battchikova Natalia,
Vainonen Julia P.,
Vorontsova Natalia,
Keränen Mika,
Carmel Dalton, Aro Eva-Mari
Journal of Proteome Research. 2010 9(11). p.5896
Effect of red and blue light on acclimation of Chlamydomonas reinhardtii to CO2-limiting conditions
Borodin V. B.
Russian Journal of Plant Physiology. 2008 55(4). p.441
CO2-concentrating mechanisms in aquatic photosynthetic microorganisms
Espie George S, Colman Brian
Canadian Journal of Botany. 2005 83(7). p.695
Regulation of nitrogen metabolism in the marine diazotroph Trichodesmium IMS101 under varying temperatures and atmospheric CO2 concentrations
Levitan Orly,
Brown Christopher M.,
Sudhaus Stefanie,
Campbell Douglas,
LaRoche Julie, Berman‐Frank Ilana
Environmental Microbiology. 2010 12(7). p.1899
Photorespiration and carbon concentrating mechanisms: two adaptations to high O2, low CO2 conditions
Moroney James V.,
Jungnick Nadine,
DiMario Robert J., Longstreth David J.
Photosynthesis Research. 2013 117(1-3). p.121
SINGLE-CELL C4 PHOTOSYNTHESIS VERSUS THE DUAL-CELL (KRANZ) PARADIGM
Edwards Gerald E.,
Franceschi Vincent R., Voznesenskaya Elena V.
Annual Review of Plant Biology. 2004 55(1). p.173
Inorganic carbon utilisation by freshwater and marine photosynthetic microorganisms
Gordillo Francisco JL
Physiologia Plantarum. 2008 133(1). p.1
Encyclopedia of Life Sciences (2007)
Dominance and compromise in freshwater phytoplanktonic flagellates: the interaction of behavioural preferences for conflicting environmental gradients
CLEGG M. R.,
MABERLY S. C., JONES R. I.
Functional Ecology. 2004 18(3). p.371
CO2 sequestration in plants: lesson from divergent strategies
Vats S. K.,
Kumar S., Ahuja P. S.
Photosynthetica. 2011 49(4). p.481
δ13C and δ15N of particulate organic matter in the Santa Barbara Channel: drivers and implications for trophic inference
Miller RJ,
Page HM, Brzezinski MA
Marine Ecology Progress Series. 2013 474 p.53
Cyanobacterial NDH‐1 complexes: multiplicity in function and subunit composition
Battchikova Natalia, Aro Eva‐Mari
Physiologia Plantarum. 2007 131(1). p.22
Systematical δ13C investigations of TOC in aquatic plants, DIC and dissolved CO2 in lake water from three Tibetan Plateau lakes
Liu Hu,
Liu Jia,
Hu Jing,
Cao Yunning,
Xiao Shangbin, Liu Weiguo
Ecological Indicators. 2022 140 p.109060
Progress in Botany (2005)
Ecology of Cyanobacteria II (2012)
Inorganic carbon utilization by aquatic photoautotrophs and potential usages of algal primary production
Matsuda Yusuke
Photosynthesis Research. 2011 109(1-3). p.1
Plant Electrophysiology (2012)
Nutrient acquisition and limitation for the photoautotrophic growth of Synechocystis sp. PCC6803 as a renewable biomass source
Kim Hyun Woo,
Vannela Raveender,
Zhou Chao, Rittmann Bruce E.
Biotechnology and Bioengineering. 2011 108(2). p.277
Harmful Cyanobacteria (2005)
