Abstract: | Despite the high potential for oxidative stress stimulated by reduced iron, contemporary iron-depositing hot springs with circum-neutral pH are intensively populated with cyanobacteria. Therefore, studies of the physiology, diversity, and phylogeny of cyanobacteria inhabiting iron-depositing hot springs may provide insights into the contribution of cyanobacteria to iron redox cycling in these environments and new mechanisms of oxidative stress mitigation. In this study the morphology, ultrastructure, physiology, and phylogeny of a novel cyanobacterial taxon, JSC-1, isolated from an iron-depositing hot spring, were determined. The JSC-1 strain has been deposited in ATCC under the name Marsacia ferruginose, accession number BAA-2121. Strain JSC-1 represents a new operational taxonomical unit (OTU) within Leptolyngbya sensu lato. Strain JSC-1 exhibited an unusually high ratio between photosystem (PS) I and PS II, was capable of complementary chromatic adaptation, and is apparently capable of nitrogen fixation. Furthermore, it synthesized a unique set of carotenoids, but only chlorophyll a. Strain JSC-1 not only required high levels of Fe for growth (≥40 μM), but it also accumulated large amounts of extracellular iron in the form of ferrihydrite and intracellular iron in the form of ferric phosphates. Collectively, these observations provide insights into the physiological strategies that might have allowed cyanobacteria to develop and proliferate in Fe-rich, circum-neutral environments.Cyanobacteria inhabiting ferrous iron-rich hot springs with circum-neutral pH represent unique models for examining the mechanisms by which early organisms evolved to cope with such habitats common on early Earth. Such organisms have previously been shown to be resistant to Fe2+ (37) or Fe3+ (6, 7) at concentrations in the micromolar to millimolar range. Moreover, high Fe concentrations (apparent optimum of ∼0.5 mM) stimulated the growth of these cyanobacteria, which were described as siderophilic (having an affinity for iron) cyanobacteria (7).The cyanobacteria inhabiting the Chocolate Pots hot springs in Yellowstone National Park, Wyoming, were shown to have played at least a passive role in contributing to iron deposition by serving as nucleation sites for the accumulation of iron minerals and associated silica deposits (36, 38). The precipitation of external iron that encrusts the cyanobacterial cells inhabiting this hot spring appears to be dependent on the species composition and chemistry of the mat (36, 38); however, multiple anoxygenic phototrophs found in the Chocolate Pots hot springs (8) could also contribute to the formation of Fe oxides (21, 49). Therefore, only iron mineralization experiments with model cyanobacterial strains can demonstrate the role of siderophilic cyanobacteria in the formation of specific, iron-bearing minerals.An additional common feature of circum-neutral iron-depositing hot springs is elevated concentrations of hydrogen peroxide (50). Shcolnick and coauthors (41) showed that a wild type of Synechococcus sp. PCC 6803 was resistant to 8 mM H2O2 if grown with 0.3 μM Fe3+, while the same concentration of hydrogen peroxide completely inhibited the growth of this cyanobacterium if it was grown with 10 μM Fe3+. If a similar correlation between iron concentration and the magnitude of an externally applied oxidative stress were the case for siderophilic cyanobacteria, iron-depositing hot springs should be free of cyanobacteria. However, such springs are very rich with cyanobacteria (38, 7, 36), which suggests that siderophilic cyanobacteria may possess unusual mechanisms of iron homeostasis maintenance and oxidative stress mitigation. Additionally, understanding iron tolerance and phenomena associated with siderophily in oxygenic prokaryotes is also important because such siderophilic organisms might help us find applications for bioremediation of waters polluted with iron.The current work describes the morphology, ultrastructure, physiology, and phylogeny of a previously undescribed, siderophilic cyanobacterium. The results of this polyphasic characterization led to the conclusion that strain JSC-1 represents a new operational taxonomic unit (OTU). (The epithet for JSC-1, Marsacia ferruginose, was chosen in honor of Nicole Tandeau de Marsac.) Additionally, biomineralization of intracellular iron by a cyanobacterium is demonstrated for the first time. |