|
|
|
|||||||
| Zatita Virusi, anti-virus programi, firewall... |
 |
|
|
Alatke vezane za temu | Vrste prikaza |
Most archaea from hydrothermal vents appear cream, white, or faint pink. EECR1B, however, exhibits a deep Prussian blue hue when grown in a three-electrode bioreactor poised at -0.25 V (vs. Ag/AgCl). Spectrophotometry and X-ray fluorescence (XRF) revealed that the pigmentation is not due to a carotenoid, but to a cytoplasmic accumulation of reduced iron-sulfur clusters (Fe₄S₄)²⁺—a direct result of hyperactive electron uptake. The "Point" refers to the sharp, needle-like biofilm structures it forms on cathode surfaces, maximizing surface area.
Strain EECR1B, colloquially named "Blue Point" due to its distinctive cobalt-blue pigmentation under anaerobic electron-donating conditions, was isolated from a hydrothermal vent in the Pacific’s Pescadero Basin . This paper reports on its extraordinary dual capability: (1) direct extracellular electron transfer (EET) to solid-state electrodes at rates exceeding known Geobacter species, and (2) a novel, cryptic sulfur reduction pathway that operates only under high hydrostatic pressure. EECR1B challenges the current dichotomy between electrogenic bacteria and chemolithotrophic archaea, offering a new chassis for bioelectrochemical systems in extreme environments.
Authors: A. Marin, K. Deep-Sea & J. Vent Affiliation: Institute of Extreme Biogeochemistry, Hadal Observatory
Most archaea from hydrothermal vents appear cream, white, or faint pink. EECR1B, however, exhibits a deep Prussian blue hue when grown in a three-electrode bioreactor poised at -0.25 V (vs. Ag/AgCl). Spectrophotometry and X-ray fluorescence (XRF) revealed that the pigmentation is not due to a carotenoid, but to a cytoplasmic accumulation of reduced iron-sulfur clusters (Fe₄S₄)²⁺—a direct result of hyperactive electron uptake. The "Point" refers to the sharp, needle-like biofilm structures it forms on cathode surfaces, maximizing surface area.
Strain EECR1B, colloquially named "Blue Point" due to its distinctive cobalt-blue pigmentation under anaerobic electron-donating conditions, was isolated from a hydrothermal vent in the Pacific’s Pescadero Basin . This paper reports on its extraordinary dual capability: (1) direct extracellular electron transfer (EET) to solid-state electrodes at rates exceeding known Geobacter species, and (2) a novel, cryptic sulfur reduction pathway that operates only under high hydrostatic pressure. EECR1B challenges the current dichotomy between electrogenic bacteria and chemolithotrophic archaea, offering a new chassis for bioelectrochemical systems in extreme environments. blue point eecr1b
Authors: A. Marin, K. Deep-Sea & J. Vent Affiliation: Institute of Extreme Biogeochemistry, Hadal Observatory Most archaea from hydrothermal vents appear cream, white,
