Casey Bryce
Casey Bryce
Verified email at uni-tuebingen.de
TitleCited byYear
Habitability: a review
CS Cockell, T Bush, C Bryce, S Direito, M Fox-Powell, JP Harrison, ...
Astrobiology 16 (1), 89-117, 2016
1202016
Supporting Mars exploration: BIOMEX in Low Earth Orbit and further astrobiological studies on the Moon using Raman and PanCam technology
JP De Vera, U Boettger, R de la Torre Noetzel, FJ Sánchez, D Grunow, ...
Planetary and Space Science 74 (1), 103-110, 2012
742012
Impact shocked rocks as protective habitats on an anoxic early Earth
CC Bryce, G Horneck, E Rabbow, HGM Edwards, CS Cockell
International Journal of Astrobiology 14 (1), 115-122, 2015
282015
Cryptic biogeochemical cycles: unravelling hidden redox reactions
A Kappler, C Bryce
Environmental Microbiology 19 (3), 842-846, 2017
222017
Microbial anaerobic Fe (II) oxidation–Ecology, mechanisms and environmental implications
C Bryce, N Blackwell, C Schmidt, J Otte, YM Huang, S Kleindienst, ...
Environmental microbiology 20 (10), 3462-3483, 2018
212018
Oxidation of Fe(II)–Organic Matter Complexes in the Presence of the Mixotrophic Nitrate-Reducing Fe(II)-Oxidizing Bacterium Acidovorax sp. BoFeN1
C Peng, A Sundman, C Bryce, C Catrouillet, T Borch, A Kappler
Environmental science & technology 52 (10), 5753-5763, 2018
192018
Rock geochemistry induces stress and starvation responses in the bacterial proteome
CC Bryce, T Le Bihan, SF Martin, JP Harrison, T Bush, B Spears, A Moore, ...
Environmental microbiology 18 (4), 1110-1121, 2016
92016
Imaging Organic–Mineral Aggregates Formed by Fe (II)-Oxidizing Bacteria Using Helium Ion Microscopy
JM Byrne, M Schmidt, T Gauger, C Bryce, A Kappler
Environmental Science & Technology Letters 5 (4), 209-213, 2018
82018
Organic Matter Complexation Promotes Fe(II) Oxidation by the Photoautotrophic Fe(II)-Oxidizer Rhodopseudomonas palustris TIE-1
C Peng, C Bryce, A Sundman, T Borch, A Kappler
ACS Earth and Space Chemistry 3 (4), 531-536, 2019
52019
The UK Centre for Astrobiology: A Virtual Astrobiology Centre. Accomplishments and Lessons Learned, 2011–2016
CS Cockell, B Biller, C Bryce, C Cousins, S Direito, D Forgan, ...
Astrobiology 18 (2), 224-243, 2018
52018
Cryptic cycling of complexes containing Fe (III) and organic matter by phototrophic Fe (II)-oxidizing bacteria
C Peng, C Bryce, A Sundman, A Kappler
Appl. Environ. Microbiol. 85 (8), e02826-18, 2019
22019
Draft genome sequence of Chlorobium sp. strain N1, a marine Fe (II)-oxidizing green sulfur bacterium
C Bryce, N Blackwell, D Straub, S Kleindienst, A Kappler
Microbiol Resour Announc 8 (18), e00080-19, 2019
12019
Proteome response of a metabolically flexible anoxygenic phototroph to Fe (II) oxidation
C Bryce, M Franz-Wachtel, NC Nalpas, J Miot, K Benzerara, JM Byrne, ...
Appl. Environ. Microbiol. 84 (16), e01166-18, 2018
12018
BIOMEX: Three different steps to approach a systematic determination of habitats and stable biosignatures in space-and Mars-like environments
JPP de Vera, U Böttger, A Lorek, D Wolter, HW Hübers, ...
12014
Iron mineral dissolution during permafrost thaw releases associated organic carbon
MS Patzner, CW Mueller, M Malusova, V Nikeleit, T Scholten, ...
EarthArXiv, 2020
2020
How did the evolution of oxygenic photosynthesis influence the temporal and spatial development of the microbial iron cycle on ancient earth?
M Schad, KO Konhauser, P Sánchez-Baracaldo, A Kappler, C Bryce
Free Radical Biology and Medicine, 2019
2019
Photoferrotrophy
C Bryce, A Kappler
Encyclopedia of Astrobiology, 1-3, 2019
2019
Microbial stress in rock habitats
CC Bryce
The University of Edinburgh, 2015
2015
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Articles 1–18