Shuhei Ono scite author profile

A deep sleep in coal beds Deep below the ocean floor, microorganisms from forest soils continue to thrive. Inagaki et al. analyzed the microbial communities in several drill cores off the coast of Japan, some sampling more than 2 km below the seafloor (see the Perspective by Huber). Although cell counts decreased with depth, deep coal beds harbored active communities of methanogenic bacteria. These communities were more similar to those found in forest soils than in other deep marine sediments. Science , this issue p. 420 ; see also p. 376

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Nonequilibrium clumped isotope signals in microbial methane

Wang

Gruen

Lollar

et al. 2015

Science

219

338

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What controls clumped isotopes? Stable isotopes of a molecule can clump together in several combinations, depending on their mass. Even for simple molecules such as O 2 , which can contain 16 O, 17 O, and 18 O in various combinations, clumped isotopes can potentially reveal the temperatures at which molecules form. Away from equilibrium, however, the pattern of clumped isotopes may reflect a complex array of processes. Using high-resolution gas-phase mass spectrometry, Yeung et al. found that biological factors influence the clumped isotope signature of oxygen produced during photosynthesis (see the Perspective by Passey). Similarly, Wang et al. showed that away from equilibrium, kinetic effects causing isotope clumping can lead to overestimation of the temperature at which microbially produced methane forms. Science , this issue p. 431; p. 428; see also p. 394

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Large Sulfur Isotope Fractionation Does Not Require Disproportionation

Sim

Bosak

Ono

2011

Science

533

338

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The composition of sulfur isotopes in sedimentary sulfides and sulfates traces the sulfur cycle throughout Earth's history. In particular, depletions of sulfur-34 ((34)S) in sulfide relative to sulfate exceeding 47 per mil (‰) often serve as a proxy for the disproportionation of intermediate sulfur species in addition to sulfate reduction. Here, we demonstrate that a pure, actively growing culture of a marine sulfate-reducing bacterium can deplete (34)S by up to 66‰ during sulfate reduction alone and in the absence of an extracellular oxidative sulfur cycle. Therefore, similar magnitudes of sulfur isotope fractionation in sedimentary rocks do not unambiguously record the presence of other sulfur-based metabolisms or the stepwise oxygenation of Earth's surface environment during the Proterozoic.

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New insights into Archean sulfur cycle from mass-independent sulfur isotope records from the Hamersley Basin, Australia

Ono

Eigenbrode

Pavlov³

et al. 2003

Earth and Planetary Science Letters

329

273

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Shuhei Ono

Exploring deep microbial life in coal-bearing sediment down to ~2.5 km below the ocean floor

Nonequilibrium clumped isotope signals in microbial methane

Large Sulfur Isotope Fractionation Does Not Require Disproportionation

New insights into Archean sulfur cycle from mass-independent sulfur isotope records from the Hamersley Basin, Australia

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