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1. Acquisition of elemental sulfur by sulfur‐oxidising Sulfolobales

   https://doi.org/10.1111/1462-2920.16691  

   Fernandes‐Martins, Maria_C; Springer, Carli; Colman, Daniel_R; Boyd, Eric_S (August 2024, Environmental Microbiology)

   Abstract Elemental sulfur (S₈⁰)‐oxidising Sulfolobales (Archaea) dominate high‐temperature acidic hot springs (>80°C, pH <4). However, genomic analyses of S₈⁰‐oxidising members of the Sulfolobales reveal a patchy distribution of genes encoding sulfur oxygenase reductase (SOR), an S₈⁰disproportionating enzyme attributed to S₈⁰oxidation. Here, we report the S₈⁰‐dependent growth of two Sulfolobales strains previously isolated from acidic hot springs in Yellowstone National Park, one of which associated with bulk S₈⁰during growth and one that did not. The genomes of each strain encoded different sulfur metabolism enzymes, with only one encoding SOR. Dialysis membrane experiments showed that direct contact is not required for S₈⁰oxidation in the SOR‐encoding strain. This is attributed to the generation of hydrogen sulfide (H₂S) from S₈⁰disproportionation that can diffuse out of the cell to solubilise bulk S₈⁰to form soluble polysulfides (S_x²⁻) and/or S₈⁰nanoparticles that readily diffuse across dialysis membranes. The Sulfolobales strain lacking SOR required direct contact to oxidise S₈⁰, which could be overcome by the addition of H₂S. High concentrations of S₈⁰inhibited the growth of both strains. These results implicate alternative strategies to acquire and metabolise sulfur in Sulfolobales and have implications for their distribution and ecology in their hot spring habitats. 

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2. Phylogenomic analysis of novel Diaforarchaea is consistent with sulfite but not sulfate reduction in volcanic environments on early Earth

   https://doi.org/10.1038/s41396-020-0611-9  

   Colman, Daniel R.; Lindsay, Melody R.; Amenabar, Maximiliano J.; Fernandes-Martins, Maria C.; Roden, Eric R.; Boyd, Eric S. (February 2020, The ISME Journal)

   Abstract The origin(s) of dissimilatory sulfate and/or (bi)sulfite reducing organisms (SRO) remains enigmatic despite their importance in global carbon and sulfur cycling since at least 3.4 Ga. Here, we describe novel, deep-branching archaeal SRO populations distantly related to other Diaforarchaea from two moderately acidic thermal springs. Dissimilatory (bi)sulfite reductase homologs, DsrABC, encoded in metagenome assembled genomes (MAGs) from spring sediments comprise one of the earliest evolving Dsr lineages. DsrA homologs were expressed in situ under moderately acidic conditions. MAGs lacked genes encoding proteins that activate sulfate prior to (bi)sulfite reduction. This is consistent with sulfide production in enrichment cultures provided sulfite but not sulfate. We suggest input of volcanic sulfur dioxide to anoxic spring-water yields (bi)sulfite and moderately acidic conditions that favor its stability and bioavailability. The presence of similar volcanic springs at the time SRO are thought to have originated (>3.4 Ga) may have supplied (bi)sulfite that supported ancestral SRO. These observations coincide with the lack of inferred SO42− reduction capacity in nearly all organisms with early-branching DsrAB and which are near universally found in hydrothermal environments. 

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3. Subsurface Archaea associated with rapid geobiological change in a model Yellowstone hot spring

   https://doi.org/10.1038/s43247-022-00542-2  

   Colman, Daniel_R; Amenabar, Maximiliano_J; Fernandes-Martins, Maria_C; Boyd, Eric_S (September 2022, Communications Earth & Environment)

   Abstract Despite over a century of study, it is unknown if continental hydrothermal fields support high-temperature subsurface biospheres. Cinder Pool is among the deepest hot springs in Yellowstone and is widely studied due to unique sulfur geochemistry that is attributed to hydrolysis of molten elemental sulfur at ∼18 m depth that promotes several chemical reactions that maintain low sulfide, low oxygen, and a moderate pH of ∼4.0. Following ∼100 years of stability, Cinder Pool underwent extreme visual and chemical change (acidification) in 2018. Here, we show that depth-resolved geochemical and metagenomic-based microbial community analyses pre- (2016) and post-acidification (2020) indicate the changes are likely attributable to feedbacks between geological/geochemical processes, sulfur oxidation by subsurface Sulfolobales Archaea, and the disappearance of molten sulfur at depth. These findings underscore the dynamic and rapid feedback between the geosphere and biosphere in continental hydrothermal fields and suggest subsurface biospheres to be more prevalent in these systems than previously recognized. 

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4. Chemical Speciation: Defining the Niche of Hot Spring Ammonia-Oxidizing Archaea (Oral Presentation)

   Weeks, Katelyn; Trembath-Reichert, Elizabeth; Robare, Jordyn; Debes, Vincent R; Howells, Alta; Boyer, Grayson; Shock, Everett L (July 2025, Goldschmidt 2025 Conference)

   The availability of chemical energy supplies is fundamental to environmental and planetary habitability. However, the presence of a chemical energy supply does not guarantee the presence of microorganisms capable of consuming it. In this study, chemical energy supplies available in Yellowstone National Park (YNP) hot springs were calculated, and the results indicate that ammonia oxidation, calculated using total dissolved ammonia, is one of the major energy supplies. Nevertheless, known ammonia-oxidizers (AO) are only present in a small fraction of the hot springs tested. Where AO are present, they do not dominate the microbial communities (relative abundances <5%), even in cases where total dissolved ammonia oxidation is the richest energy supply. The AO in YNP hot springs are predominantly ammonia-oxidizing archaea (AOA), which tend to favor environments with low total ammonia (sum of NH3 and NH4+) concentrations, despite the requirement of ammonia (NH3) as a substrate. Hot spring pH and temperature determine the ratio of NH3 to NH4+ and, consequently, NH3 availability to resident AOA. In this study, total ammonia measurements were collected from YNP hot spring samples using ion chromatography in coordination with biological sampling. DNA was extracted from simultaneously collected samples for 16S rRNA gene sequencing and analysis, and for the identification of known AOA. The WORM-portal (https://worm-portal.asu.edu/) was used to speciate the total ammonia measurements into ammonia and ammonium activities. By performing speciation calculations, we identified a potential lower limit for substrate (NH3) availability and a potential upper limit for NH4+ concentrations for the YNP hot spring AOA. Thus, the niche for AOA across YNP hot springs is dictated by the form of the total dissolved ammonia present, not by the energy supply available for total dissolved ammonia oxidation. 

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5. Diverse Sulfuriferula spp. from sulfide mineral weathering environments oxidize ferrous iron and reduced inorganic sulfur compounds

   https://doi.org/10.1128/aem.00216-25  

   Hobart, Kathryn K; Walker, Gabriel M; Feinberg, Joshua M; Bailey, Jake V; Jones, Daniel S (July 2025, Applied and Environmental Microbiology)

   Spear, John R (Ed.)

   ABSTRACT Microorganisms are important catalysts for the oxidation of reduced inorganic sulfur compounds. One environmentally important source of reduced sulfur is metal sulfide minerals that occur in economic mineral deposits and mine waste. Previous research found thatSulfuriferulaspp. were abundant and active in long-term weathering experiments with simulated waste rock and tailings from the Duluth Complex, Northern Minnesota. We, therefore, isolated several strains ofSulfuriferulaspp. from these long-term experiments and characterized their metabolic and genomic properties to provide insight into microbe-mineral interactions and the microbial biogeochemistry in these and other moderately acidic to circumneutral environments. TheSulfuriferulastrains are all obligate chemolithoautotrophs capable of oxidizing inorganic sulfur compounds and ferrous iron. The strains grew over different pH ranges, but all grew between pH 4.5 and 7, matching the weathering conditions of the Duluth Complex rocks. All strains grew on the iron-sulfide mineral pyrrhotite (Fe_{1 −x}S, 0 <x< 0.125) as the sole energy source, as well as hydrogen sulfide and thiosulfate, which are products of sulfide mineral breakdown. Despite their metabolic similarities, each strain encodes a distinct pathway for the oxidation of reduced inorganic sulfur compounds as well as differences in nitrogen metabolism that reveal diverse genomic capabilities among the group. Our results show thatSulfuriferulaspp. are primary producers that likely play a role in sulfide mineral breakdown in moderately acidic to circumneutral mine waste, and the metabolic diversity within the genus may explain their success in sulfide mineral-rich and other sulfidic environments. IMPORTANCEMetal sulfide minerals, such as pyrite and pyrrhotite, are one of the main sources of reduced sulfur in the global sulfur cycle. The chemolithotrophic microorganisms that break down these minerals in natural and engineered settings are catalysts for biogeochemical sulfur cycling and have important applications in biotechnological processes such as biomining and bioremediation.Sulfuriferulais a recently described genus of sulfur-oxidizing bacteria that are abundant primary producers in diverse terrestrial environments, including waste rock and tailings from metal mining operations. In this study, we explored the genomic and metabolic properties of new isolates from this genus, and the implications for their ecophysiology and biotechnological potential in ore and waste from economic mineral deposits. 

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