Polysaccharide hydrolysis in the presence of oil and dispersants: Insights into potential degradation pathways of exopolymeric substances (EPS) from oil-degrading bacteria. Elementa, (7):31, BioOne, 2019. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Microbial anaerobic Fe(II) oxidation – Ecology, mechanisms and environmental implications. Environmental microbiology, (20)10:3462-3483, Wiley, 2018. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Biodegradation of crude oil and dispersants in deep seawater from the Gulf of Mexico: Insights from ultra-high resolution mass spectrometry. Deep-sea research. Part 2, Topical studies in oceanography, (129):108-118, Elsevier, 2016. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Insights into Nitrate-Reducing Fe(II) Oxidation Mechanisms through Analysis of Cell-Mineral Associations, Cell Encrustation, and Mineralogy in the Chemolithoautotrophic Enrichment Culture KS. Applied and environmental microbiology, (83)13:e00752-17, American Society for Microbiology, 2017. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Global Aerobic Degradation of Hydrocarbons in Aquatic Systems. In Fernando Rojo (Eds.), Aerobic Utilization of Hydrocarbons, Oils, and Lipids, 797-814, Springer, 2017. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Response and oil degradation activities of a northeast Atlantic bacterial community to biogenic and synthetic surfactants. Microbiome, (9):191, Springer, 2021. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Genomic Insights into Two Novel Fe(II)-Oxidizing Zetaproteobacteria Isolates Reveal Lifestyle Adaption to Coastal Marine Sediments. Applied and environmental microbiology, (86)17:e01160-20, American Society for Microbiology, 2020. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Presence of Fe(II) and nitrate shapes aquifer-originating communities leading to an autotrophic enrichment dominated by an Fe(II)-oxidizing Gallionellaceae sp. FEMS microbiology ecology, (97)11:fiab145, Oxford Univ. Press, 2021. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Insights into Carbon Metabolism Provided by Fluorescence In Situ Hybridization-Secondary Ion Mass Spectrometry Imaging of an Autotrophic, Nitrate-Reducing, Fe(II)-Oxidizing Enrichment Culture. Applied and environmental microbiology, (84)9:e02166-17, American Society for Microbiology, 2018. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Microbial communities contribute to the elimination of As, Fe, Mn, and NH4+ from groundwater in household sand filters. The science of the total environment, (838)4:156496, Elsevier, 2022. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Responses of Microbial Communities to Hydrocarbon Exposures. Oceanography, (29)3:136-149, The Oceanography Society, 2016. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Microbial iron cycling during palsa hillslope collapse promotes greenhouse gas emissions before complete permafrost thaw. Communications earth & environment, (3):76, Springer, 2022. [PUMA: fis liste oa ubs_10002 ubs_20002 ubs_30026]
Fermentation, methanotrophy and methanogenesis influence sedimentary Fe and As dynamics in As-affected aquifers in Vietnam. The science of the total environment, (779):146501, Elsevier, 2021. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Seasonal Fluctuations in Iron Cycling in Thawing Permafrost Peatlands. Environmental science & technology, (56)7:4620-4631, American Chemical Society, 2022. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Arsenic mobilization by anaerobic iron-dependent methane oxidation. Communications earth & environment, (1):42, Springer, 2020. [PUMA: fis liste oa ubs_10002 ubs_20002 ubs_30026]
Draft Genome Sequence of Chlorobium sp. Strain N1, a Marine Fe(II)-Oxidizing Green Sulfur Bacterium. Microbiology resource announcements, (8)18:e00080-19, American Society for Microbiology, 2019. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Draft Genome Sequence of a Strictly Anaerobic Dichloromethane-Degrading Bacterium. Microbiology resource announcements, (3)4:e00037-16, American Society for Microbiology, 2016. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Reply to Prince et al.: Ability of chemical dispersants to reduce oil spill impacts remains unclear. Proceedings of the National Academy of Sciences of the United States of America, (113)11:E1422-E1423, NAS, 2016. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Distribution and in situ abundance of sulfate-reducing bacteria in diverse marine hydrocarbon seep sediments. Environmental microbiology, (14)10:2689-2710, Wiley, 2012. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]
Uncovering Microbial Hydrocarbon Degradation Processes: The Promise of Stable Isotope Probing. In Andreas Teske, and Verena Carvalho (Eds.), Marine Hydrocarbon Seeps : Microbiology and Biogeochemistry of a Global Marine Habitat, 183-199, Springer, 2020. [PUMA: fis liste ubs_10002 ubs_20002 ubs_30026]