Luminescent Whole-Cell Cyanobacterial Bioreporter for Measuring Fe Availability in Diverse Marine Environments

Boyanapalli, Ramakrishna; Bullerjahn, George S.; Pohl, Christa; Croot, Peter; Boyd, Philip W.; McKay, R. Michael L.

doi:10.1128/aem.01670-06

Cited by 45 publications

(55 citation statements)

References 41 publications

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“…Their study though is not carried out under natural daylight conditions and thus excludes Fe(II). Particularly in the context of iron limitation when the Fe(II) pool is excluded, our data suggest that Fe(II) plays a major role in iron acquisition by phytoplankton, namely diazotrophic cyanobacteria, in the Baltic Sea and may thus alleviate iron limitation as suggested for cyanobacterial bloom development and nitrogen fixation in the Baltic Sea (Stal et al, 1999;Schubert et al, 2007;Boyanapalli et al, 2007).…”

Section: Significance Of Fe(ii) For Cyanobacterial Growthmentioning

confidence: 99%

“…Boyanapalli et al (2007), using a luminescent bioreporter approach and water samples from the Gotland Deep station, demonstrate that only a proportion of the dissolved iron fraction is bioavailable and suggest potential iron limitation. Their study though is not carried out under natural daylight conditions and thus excludes Fe(II).…”

Section: Significance Of Fe(ii) For Cyanobacterial Growthmentioning

confidence: 99%

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Dissolved iron (II) in the Baltic Sea surface water and implications for cyanobacterial bloom development

Breitbarth

Gelting²,

Walve

et al. 2009

Biogeosciences

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Abstract. Iron chemistry measurements were conducted during summer 2007 at two distinct locations in the Baltic Sea (Gotland Deep and Landsort Deep) to evaluate the role of iron for cyanobacterial bloom development in these estuarine waters. Depth profiles of Fe(II) were measured by chemiluminescent flow injection analysis (CL-FIA). Up to 0.9 nmol Fe(II) L −1 were detected in light penetrated surface waters, which constitutes up to 20% to the dissolved Fe pool. This bioavailable iron source is a major contributor to the Fe requirements of Baltic Sea phytoplankton and apparently plays a major role for cyanobacterial bloom development during our study. Measured Fe(II) half life times in oxygenated water exceed predicted values and indicate organic Fe(II) complexation. Potential sources for Fe(II) ligands, including rainwater, are discussed. Fe(II) concentrations of up to 1.44 nmol L −1 were detected at water depths below the euphotic zone, but above the oxic anoxic interface. Mixed layer depths after strong wind events are not deep enough in summer time to penetrate the oxic-anoxic boundary layer. However, Fe(II) from anoxic bottom water may enter the sub-oxic zone via diapycnal mixing and diffusion.Correspondence to: E. Breitbarth (ebreitbarth@chemistry.otago.ac.nz)

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Section: Significance Of Fe(ii) For Cyanobacterial Growthmentioning

confidence: 99%

Section: Significance Of Fe(ii) For Cyanobacterial Growthmentioning

confidence: 99%

Dissolved iron (II) in the Baltic Sea surface water and implications for cyanobacterial bloom development

Breitbarth

Gelting²,

Walve

et al. 2009

Biogeosciences

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“…Apart from the effect of offshore transport, atmospheric input of high Fe concentrations may facilitate fast plankton growth followed by its degradation and production of DOM to support the heterotrophic bacterial community. In this context, the bioavailability and solubility of iron may play an important role (Jickells et al, 2005;Boyanapalli et al, 2007). In a recent microcosm experiment, the addition of atmospheric dust caused a drastic increase (12-fold) in the pathogenic Vibrio cholerae population within a day (Lipp and Westrich, 2011).…”

Section: Dom As An Important Regulator Of Vibrio and Other Bacterial mentioning

confidence: 99%

Biogeochemical controls on the bacterial populations in the eastern Atlantic Ocean

et al. 2011

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Abstract.Little is known about bacterial dynamics in the oligotrophic ocean, particularly about cultivable bacteria. We examined the abundance of total and cultivable bacteria in relation to changes in biogeochemical conditions in the eastern Atlantic Ocean with special regard to Vibrio spp., a group of bacteria that can cause diseases in human and aquatic organisms. Surface, deep water and plankton (<20 µm, 20-55 µm and >55 µm) samples were collected between 50 • N and 24 • S. Chlorophyll-a was very low (<0.3 µg l −1 ) in most areas of the nutrient-poor Atlantic, except at a few locations near upwelling regions. In surface water, dissolved organic carbon (DOC) and nitrogen (DON) concentrations were 64-95 µM C and 2-10 µM N accounting for ≥90 % and ≥76 % of total organic C and N, respectively. DOC and DON gradually decreased to ∼45 µM C and <5 µM N in the bottom water. In the surface layer, culture independent total bacteria and other prokaryotes represented by 4 -6-diamidino-2-phenylindole (DAPI) counts, ranged mostly between 10 7 and 10 8 cells l −1 , while cultivable bacterial counts (CBC) and Vibrio spp. were found at concentrations of 10 4 -10 7 and 10 2 -10 5 colony forming units (CFU) l −1 , respectively. Most bacteria (>99 %) were found in the nanoplankton fraction (<20 µm), however, bacterial abundance did not correlate with suspended particulates (chlorophyll-a, particulateCorrespondence to: R. J. Lara (ruben.lara@zmt-bremen.de) organic C [POC] and N [PON]). Instead, we found a highly significant correlation between bacterial abundance and temperature (p < 0.001) and a significant correlation with DOC and DON (p < 0.005 and < 0.01, respectively). In comparison to CBC and DAPI-stained prokaryotes, cultivable Vibrio showed a stronger and highly significant correlation with DOC and DON (p < 0.0005 and p < 0.005, respectively). In cold waters of the mesopelagic and abyssal zones, CBC was 50 to 100-times lower than in the surface layer; however, cultivable Vibrio spp. could be isolated from the bathypelagic zone and even near the seafloor (average ∼10 CFU l −1 ). The depth-wise decrease in CBC and Vibrio coincided with the decrease in both DOC and POC. Our study indicates that Vibrio and other bacteria may largely depend on dissolved organic matter to survive in nutrient-poor oceanic habitats.

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“…Utilization of laboratory based extensive instrumentation such as FlFFF, x-ray spectroscopy with TEM microscopy, as well as bioreporters, molecular techniques and genomic information allow for in depth studies and visualization of Fe limitation and Fe organic matter interactions (e.g. Heldal et al, 1996;Toner et al, 2009;Stolpe et al, 2005) and particularly also of iron bioavailability (Lam et al, 2006;Boyanapalli et al, 2007;Hassler et al, 2006). Nevertheless, some methods still depend on high material/biomass concentrations and future development and work may lead towards more direct measurement techniques overcoming pre-concentration artifacts.…”

Section: Linking Biological Processes To Iron Chemistrymentioning

confidence: 99%

Iron biogeochemistry across marine systems – progress from the past decade

et al. 2010

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Abstract. Based on an international workshop (Gothenburg, 14-16 May 2008), this review article aims to combine interdisciplinary knowledge from coastal and open ocean research on iron biogeochemistry. The major scientific findings of the past decade are structured into sections on natural and artificial iron fertilization, iron inputs into coastal and estuarine systems, colloidal iron and organic matter, and biological processes. Potential effects of global climate change, particularly ocean acidification, on iron biogeochemistry are discussed. The findings are synthesized into recommendations for future research areas.Correspondence to: E. Breitbarth (ebreitbarth@chemistry.otago.ac.nz)

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Luminescent Whole-Cell Cyanobacterial Bioreporter for Measuring Fe Availability in Diverse Marine Environments

Cited by 45 publications

References 41 publications

Dissolved iron (II) in the Baltic Sea surface water and implications for cyanobacterial bloom development

Dissolved iron (II) in the Baltic Sea surface water and implications for cyanobacterial bloom development

Biogeochemical controls on the bacterial populations in the eastern Atlantic Ocean

Iron biogeochemistry across marine systems – progress from the past decade

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