Add to ORKGSparse microbial populations persist from seafloor to basement in the slowly accumulating oxic sediment of the oligotrophic South Pacific Gyre (SPG). The physiological status of these communities, including their substrate metabolism, is previously unconstrained. Here we show that diverse aerobic members of communities in SPG sediments (4.3‒101.5 Ma) are capable of readily incorporating carbon and nitrogen substrates and dividing. Most of the 6986 individual cells analyzed with nanometer-scale secondary ion mass spectrometry (NanoSIMS) actively incorporated isotope-labeled substrates. Many cells responded rapidly to incubation conditions, increasing total numbers by 4 orders of magnitude and taking up labeled carbon and nitrogen within 68 d...
Scientific ocean drilling has greatly advanced the understanding of subseafloor sedimentary life. St...
Studies of deeply buried, sedimentary microbial communities and associated biogeochemical processes ...
Selection of microorganisms in marine sediment is shaped by energy-yielding electron acceptors for r...
Sparse microbial populations persist from seafloor to basement in the slowly accumulating oxic sedim...
Microbial life in marine sediment contributes substantially to global biomass and is a crucial compo...
The discovery of aerobic microbial communities in nutrient-poor sediments below the seafloor begs th...
The low-productivity South Pacific Gyre (SPG) is Earth\u27s largest oceanic province. Its sediment a...
Ammonia-oxidizing archaea (AOA) dominate microbial communities throughout oxic subseafloor sediment ...
Microbial communities can subsist at depth in marine sediments without fresh supply of organic matte...
The depth of oxygen penetration into marine sediments differs considerably from one region to anothe...
No other environment hosts as many microbial cells as the marine sedimentary biosphere. While the ma...
Marine microorganisms play a fundamental role in the global carbon cycle by mediating the sequestrat...
More than half of the global ocean floor is draped by nutrient-starved sediments characterized by de...
Oceanic ridge flank systems represent one of the largest and leastexplored microbial habitats on Ear...
There is abundant evidence that prokaryotic cells live deep beneath the sea floor. Pore water chemic...
Scientific ocean drilling has greatly advanced the understanding of subseafloor sedimentary life. St...
Studies of deeply buried, sedimentary microbial communities and associated biogeochemical processes ...
Selection of microorganisms in marine sediment is shaped by energy-yielding electron acceptors for r...
Sparse microbial populations persist from seafloor to basement in the slowly accumulating oxic sedim...
Microbial life in marine sediment contributes substantially to global biomass and is a crucial compo...
The discovery of aerobic microbial communities in nutrient-poor sediments below the seafloor begs th...
The low-productivity South Pacific Gyre (SPG) is Earth\u27s largest oceanic province. Its sediment a...
Ammonia-oxidizing archaea (AOA) dominate microbial communities throughout oxic subseafloor sediment ...
Microbial communities can subsist at depth in marine sediments without fresh supply of organic matte...
The depth of oxygen penetration into marine sediments differs considerably from one region to anothe...
No other environment hosts as many microbial cells as the marine sedimentary biosphere. While the ma...
Marine microorganisms play a fundamental role in the global carbon cycle by mediating the sequestrat...
More than half of the global ocean floor is draped by nutrient-starved sediments characterized by de...
Oceanic ridge flank systems represent one of the largest and leastexplored microbial habitats on Ear...
There is abundant evidence that prokaryotic cells live deep beneath the sea floor. Pore water chemic...
Scientific ocean drilling has greatly advanced the understanding of subseafloor sedimentary life. St...
Studies of deeply buried, sedimentary microbial communities and associated biogeochemical processes ...
Selection of microorganisms in marine sediment is shaped by energy-yielding electron acceptors for r...