Mineral iron dissolution in Trichodesmium colonies: The role of O₂ and pH microenvironments

Abstract: Colonies of the N2‐fixing cyanobacterium Trichodesmium can harbor distinct chemical microenvironments that may assist the colonies in acquiring mineral iron from dust. Here, we characterized O2 and pH gradients in and around Trichodesmium colonies by microsensor measurements on > 170 colonies collected in the Gulf of Eilat over ∼ 2 months. O2 concentrations and pH values in the center of single colonies decreased in the dark due to respiration, reaching minimum values of 70 μmol L−1 and 7.7, whereas in the lig… Show more

“… 12 − 15 Similarly, with natural Phaeocystis colonies, it was shown that Mn accumulation in the algae was significantly influenced by the pH and O 2 concentrations in the mucilaginous matrix in which the cells were imbedded. 16 In contrast, Eichner et al 17 reported that the utilization of Fe minerals by Trichodesmium colonies was little influenced by changes in pH and O 2 in and around the colonies. Moreover, two modeling studies showed that speciation of Si 18 and Cd 19 in the phycosphere differed from that in the bulk media.…”

Unravelling Metal Speciation in the Microenvironment Surrounding Phytoplankton Cells to Improve Predictions of Metal Bioavailability

“… 12 − 15 Similarly, with natural Phaeocystis colonies, it was shown that Mn accumulation in the algae was significantly influenced by the pH and O 2 concentrations in the mucilaginous matrix in which the cells were imbedded. 16 In contrast, Eichner et al 17 reported that the utilization of Fe minerals by Trichodesmium colonies was little influenced by changes in pH and O 2 in and around the colonies. Moreover, two modeling studies showed that speciation of Si 18 and Cd 19 in the phycosphere differed from that in the bulk media.…”

Unravelling Metal Speciation in the Microenvironment Surrounding Phytoplankton Cells to Improve Predictions of Metal Bioavailability

“…Eichner et al. (2020) showed plausible molecular evidence that colonies of Trichodesmium (marine cyanobacterium) can mediate Fe leaching. Fe leaching is a fundamental bacterial process for decoupling from Fe (Smolders et al., 2006), and may provide cyanobacteria with an increased benefit when competing with eukaryotes in oligotrophic systems.…”

“…4 bound in the sediment by modification of the redox potential, cyanobacteria can also mediate this process under oxic conditions via siderophore production and scavenging of bound Fe (Wilhelm & Trick, 1994), alleviating Fe limitation. Eichner et al (2020) showed plausible molecular evidence that colonies of Trichodesmium (marine cyanobacterium) can mediate Fe leaching. Fe leaching is a fundamental bacterial process for decoupling PO 3 − 4 from Fe (Smolders et al, 2006), and may provide cyanobacteria with an increased benefit when competing with eukaryotes in oligotrophic systems.…”

Cyanobacterial blooms in oligotrophic lakes: Shifting the high‐nutrient paradigm

“…However, it has been challenged by recent studies that observe higher O 2 in a colony than the environment [232] and higher N 2 fixation rates in a free-floating filament than in a colony [84] . Despite that, there are still cases with lower O 2 in a colony during the middle of the day [84] , [233] and models would be useful in exploring the low O 2 effect as well as why free-floating filaments have higher rates of N 2 fixation.…”

Quantitative models of nitrogen-fixing organisms