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References (42)
-
Woodward Woodward (2002)
Nanomolar detection of phosphate and nitrate using liquid waveguard technologyEOS, 83
-
S. Giovannoni, H. Tripp, S. Givan, M. Podar, K. Vergin, Damon Baptista, L. Bibbs, Jonathan Eads, T. Richardson, M. Noordewier, M. Rappé, J. Short, J. Carrington, E. Mathur (2005)
Genome Streamlining in a Cosmopolitan Oceanic BacteriumScience, 309
-
Lisa Moore, M. Ostrowski, D. Scanlan, K. Feren, T. Sweetsir (2005)
Ecotypic variation in phosphorus-acquisition mechanisms within marine picocyanobacteriaAquatic Microbial Ecology, 39
-
I. Mary, Jane Heywood, B. Fuchs, R. Amann, G. Tarran, P. Burkill, M. Zubkov (2006)
SAR11 dominance among metabolically active low nucleic acid bacterioplankton in surface waters along an Atlantic Meridional TransectAquatic Microbial Ecology, 45
-
R. Wright, J. Hobbie (1966)
Use of Glucose and Acetate by Bacteria and Algae in Aquatic EcosystemsEcology, 47
-
T. Ho, A. Quigg, Z. Finkel, A. Milligan, K. Wyman, P. Falkowski, F. Morel (2003)
THE ELEMENTAL COMPOSITION OF SOME MARINE PHYTOPLANKTON 1Journal of Phycology, 39
-
M. Zubkov, P. Burkill (2006)
Syringe pumped high speed flow cytometry of oceanic phytoplanktonCytometry Part A, 69A
-
T. Thingstad, M. Krom, R. Mantoura, R. Mantoura, G. Flaten, Steve Groom, B. Herut, N. Kress, C. Law, C. Law, A. Pasternak, P. Pitta, S. Psarra, F. Rassoulzadegan, Tsuneo Tanaka, A. Tselepides, P. Wassmann, E. Woodward, C. Riser, G. Zodiatis, T. Zohary (2005)
Nature of Phosphorus Limitation in the Ultraoligotrophic Eastern MediterraneanScience, 309
-
S. Bertilsson, O. Berglund, D. Karl, S. Chisholm (2003)
Elemental composition of marine Prochlorococcus and Synechococcus: Implications for the ecological stoichiometry of the seaLimnology and Oceanography, 48
-
K. Zwirglmaier, Jane Heywood, K. Chamberlain, E. Woodward, M. Zubkov, Dave Scanlan (2007)
Basin-scale distribution patterns of picocyanobacterial lineages in the Atlantic Ocean.Environmental microbiology, 9 5
-
K. Arrigo (2005)
Marine microorganisms and global nutrient cyclesNature, 437
-
Jingfeng Wu, W. Sunda, E. Boyle, D. Karl (2000)
Phosphate depletion in the western North Atlantic Ocean.Science, 289 5480
-
N. West, D. Scanlan (1999)
Niche-partitioning of Prochlorococcus populations in a stratified water column in the eastern North Atlantic Ocean.Applied and environmental microbiology, 65 6
-
T. Moutin, T. Thingstad, F. Wambeke, D. Marie, G. Slawyk, P. Raimbault, H. Claustre (2002)
Does competition for nanomolar phosphate supply explain the predominance of the cyanobacterium Synechococcus?Limnology and Oceanography, 47
-
M. Zubkov, P. Burkill, J. Topping (2006)
Flow cytometric enumeration of DNA-stained oceanic planktonic protistsJournal of Plankton Research, 29
-
F. Lipschultz (1995)
Nitrogen-specific uptake rates of marine phytoplankton isolated from natural populations of particles by flow cytometryMarine Ecology Progress Series, 123
-
R. Kiene, L. Linn (1999)
Filter-type and sample handling affect determination of organic substrate uptake by bacterioplanktonAquatic Microbial Ecology, 17
-
S. Sañudo-Wilhelmy, Adam Kustka, C. Gobler, D. Hutchins, Min Yang, K. Lwiza, J. Burns, D. Capone, J. Raven, E. Carpenter (2001)
Phosphorus limitation of nitrogen fixation by Trichodesmium in the central Atlantic OceanNature, 411
-
William Li (1994)
Primary production of prochlorophytes, cyanobacteria, and eucaryotic ultraphytoplankton: Measurements from flow cytometric sortingLimnology and Oceanography, 39
-
M. Zubkov, G. Tarran (2005)
Amino acid uptake of Prochlorococcus spp. in surface waters across the South Atlantic Subtropical FrontAquatic Microbial Ecology, 40
-
R. Ferguson, W. Sunda (1984)
Utilization of amino acids by planktonic marine bacteria: Importance of clean technique and low substrate additions1,2Limnology and Oceanography, 29
-
M. Zubkov, G. Tarran, B. Fuchs (2004)
Depth related amino acid uptake by Prochlorococcus cyanobacteria in the Southern Atlantic tropical gyre.FEMS microbiology ecology, 50 3
-
M. Zubkov, M. Sleigh, P. Burkill, Raymond Leakey (2000)
Picoplankton community structure on the Atlantic Meridional Transect: a comparison between seasonsProgress in Oceanography, 45
-
R. Morris, M. Rappé, S. Connon, K. Vergin, William Siebold, C. Carlson, S. Giovannoni (2002)
SAR11 clade dominates ocean surface bacterioplankton communitiesNature, 420
-
A. Pernthaler, J. Pernthaler, R. Amann (2002)
Fluorescence In Situ Hybridization and Catalyzed Reporter Deposition for the Identification of Marine BacteriaApplied and Environmental Microbiology, 68
-
M. Mills, C. Ridame, M. Davey, J. Roche, R. Geider (2004)
Iron and phosphorus co-limit nitrogen fixation in the eastern tropical North AtlanticNature, 429
-
R. Amann, L. Krumholz, D. Stahl (1990)
Fluorescent-oligonucleotide probing of whole cells for determinative, phylogenetic, and environmental studies in microbiologyJournal of Bacteriology, 172
-
M. Heldal, David Scanlan, S. Norland, F. Thingstad, N. Mann (2003)
Elemental composition of single cells of various strains of marine Prochlorococcus and Synechococcus using X‐ray microanalysisLimnology and Oceanography, 48
-
A. Pernthaler, R. Amann (2004)
Simultaneous Fluorescence In Situ Hybridization of mRNA and rRNA in Environmental BacteriaApplied and Environmental Microbiology, 70
-
K. Gundersen, M. Heldal, S. Norland, D. Purdie, A. Knap (2002)
Elemental C, N, and P cell content of individual bacteria collected at the Bermuda Atlantic Time‐series Study (BATS) siteLimnology and Oceanography, 47
-
A. Martiny, Maureen Coleman, S. Chisholm (2006)
Phosphate acquisition genes in Prochlorococcus ecotypes: Evidence for genome-wide adaptationProceedings of the National Academy of Sciences, 103
-
Z. Johnson, E. Zinser, Allison Coe, N. McNulty, E. Woodward, S. Chisholm (2006)
Niche Partitioning Among Prochlorococcus Ecotypes Along Ocean-Scale Environmental GradientsScience, 311
-
J. Grillo, J. Gibson (1979)
Regulation of Phosphate Accumulation in the Unicellular Cyanobacterium SynechococcusJournal of Bacteriology, 140
-
D. Marie, F. Partensky, S. Jacquet, D. Vaulot (1997)
Enumeration and Cell Cycle Analysis of Natural Populations of Marine Picoplankton by Flow Cytometry Using the Nucleic Acid Stain SYBR Green IApplied and Environmental Microbiology, 63
-
J. Ammerman, R. Hood, D. Case, J. Cotner (2003)
Phosphorus deficiency in the Atlantic: An emerging paradigm in oceanographyEos, Transactions American Geophysical Union, 84
-
W. Schönhuber, B. Zarda, Stella Eix, R. Rippka, M. Herdman, W. Ludwig, R. Amann (1999)
In Situ Identification of Cyanobacteria with Horseradish Peroxidase-Labeled, rRNA-Targeted Oligonucleotide ProbesApplied and Environmental Microbiology, 65
-
I. Biegala, F. Not, D. Vaulot, N. Simon (2003)
Quantitative Assessment of Picoeukaryotes in the Natural Environment by Using Taxon-Specific Oligonucleotide Probes in Association with Tyramide Signal Amplification-Fluorescence In Situ Hybridization and Flow CytometryApplied and Environmental Microbiology, 69
-
B. Mooy, G. Rocap, Helen Fredricks, Colleen Evans, A. Devol (2006)
Sulfolipids dramatically decrease phosphorus demand by picocyanobacteria in oligotrophic marine environments.Proceedings of the National Academy of Sciences of the United States of America, 103 23
-
M. Karner, E. Delong, D. Karl (2001)
Archaeal dominance in the mesopelagic zone of the Pacific OceanNature, 409
-
H. Daims, A. Brühl, R. Amann, K. Schleifer, Michael Wagner (1999)
The domain-specific probe EUB338 is insufficient for the detection of all Bacteria: development and evaluation of a more comprehensive probe set.Systematic and applied microbiology, 22 3
-
D. Karl, Ricardo Letelier, L. Tupas, J. Dore, J. Christian, Dale Hebel (1997)
The role of nitrogen fixation in biogeochemical cycling in the subtropical North Pacific OceanNature, 388
-
N. West, W. Schönhuber, W. Schönhuber, Nicholas Fuller, Rudolf Amann, R. Rippka, Anton Post, D. Scanlan (2001)
Closely related Prochlorococcus genotypes show remarkably different depth distributions in two oceanic regions as revealed by in situ hybridization using 16S rRNA-targeted oligonucleotides.Microbiology, 147 Pt 7
- Publisher
- Wiley
- Copyright
- Copyright © 2007 Wiley Subscription Services, Inc., A Wiley Company
- ISSN
- 1462-2912
- eISSN
- 1462-2920
- DOI
- 10.1111/j.1462-2920.2007.01324.x
- pmid
- 17635551
- Publisher site
- See Article on Publisher Site
Abstract
Summary Little is known about the dynamics of dissolved phosphate in oligotrophic areas of the world's oceans, where concentrations are typically in the nanomolar range. Here, we have budgeted phosphate uptake by the dominant microbial groups in order to assess the effect of the microbial control of this depleted nutrient in the North Atlantic gyre. Low concentrations (2.2 ± 1.2 nM) and rapid microbial uptake (2.1 ± 2.4 nM day−1) of bioavailable phosphate were repeatedly determined in surface waters of the North Atlantic oligotrophic gyre during spring and autumn research cruises, using a radiotracer dilution bioassay technique. Upper estimates of the concentration of bioavailable phosphate were 7–55% of the dissolved mineral phosphate suggesting that a considerable part of the chemically measured nanomolar phosphate was in a form unavailable for direct microbial uptake. A 1:1 relationship (r2 = 0.96, P < 0.0001) was observed between the bioavailable total phosphate uptake and the phosphate uptake of all the flow sorted bacterioplankton cells, demonstrating that bacterioplankton were the main consumers of phosphate. Within the bacterioplankton a group of heterotrophic bacteria and Prochlorococcus phototrophic cyanobacteria, were the two major competing groups for bioavailable phosphate. These heterotrophic bacteria had low nucleic acid content and 60% of them comprised of SAR11 clade cells based on the results of fluorescence in situ hybridization. Each of the two competing bacterial groups was responsible for an average of 45% of the phosphate uptake, while Synechococcus cyanobacteria (7%) and picoplanktonic algae (0.3%) played minor roles in direct phosphate uptake. We have demonstrated that phosphate uptake in the oligotrophic gyre is rapid and dominated by two bacterial groups rather than by algae.
Journal
Environmental Microbiology – Wiley
Published: Aug 1, 2007