Admixture mapping identifies African and Amerindigenous local ancestry loci associated with fetal growth

Oxygen and silicon isotope compositions of cherts and studies of protein evolution have been interpreted to reflect ocean temperatures of 55-85 degrees C during the early Palaeoarchaean era ( approximately 3.5 billion years ago). A recent study combining oxygen and hydrogen isotope compositions of cherts, however, makes a case for Archaean ocean temperatures being no greater than 40 degrees C (ref. 5). Ocean temperature can also be assessed using the oxygen isotope composition of phosphate. Recent studies show that (18)O:(16)O ratios of dissolved inorganic phosphate (delta(18)O(P)) reflect ambient seawater temperature as well as biological processing that dominates marine phosphorus cycling at low temperature. All forms of life require and concentrate phosphorus, and as a result of biological processing, modern marine phosphates have delta(18)O(P) values typically between 19-26 per thousand (VSMOW), highly evolved from presumed source values of approximately 6-8 per thousand that are characteristic of apatite in igneous rocks and meteorites. Here we report oxygen isotope compositions of phosphates in sediments from the 3.2-3.5-billion-year-old Barberton Greenstone Belt in South Africa. We find that delta(18)O(P) values range from 9.3 per thousand to 19.9 per thousand and include the highest values reported for Archaean rocks. The temperatures calculated from our highest delta(18)O(P) values and assuming equilibrium with sea water with delta(18)O = 0 per thousand (ref. 12) range from 26 degrees C to 35 degrees C. The higher delta(18)O(P) values are similar to those of modern marine phosphate and suggest a well-developed phosphorus cycle and evolved biologic activity on the Archaean Earth.

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Precise calibration of equilibrium oxygen isotope fractionations between dissolved phosphate and water from 3 to 37 °C

Chang

Blake

2015

Geochimica et Cosmochimica Acta

123

133

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Archean phosphorus liberation induced by iron redox geochemistry

et al. 2018

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The element phosphorus (P) is central to ecosystem growth and is proposed to be a limiting nutrient for life. The Archean ocean may have been strongly phosphorus-limited due to the selective binding of phosphate to iron oxyhydroxide. Here we report a new route to solubilizing phosphorus in the ancient oceans: reduction of phosphate to phosphite by iron(II) at low (<200 °C) diagenetic temperatures. Reduction of phosphate to phosphite was likely widespread in the Archean, as the reaction occurs rapidly and is demonstrated from thermochemical modeling, experimental analogs, and detection of phosphite in early Archean rocks. We further demonstrate that the higher solubility of phosphite compared to phosphate results in the liberation of phosphorus from ferruginous sediments. This phosphite is relatively stable after its formation, allowing its accumulation in the early oceans. As such, phosphorus, not as phosphate but as phosphite, could have been a major nutrient in early pre-oxygenated oceans.

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Probing the metabolic water contribution to intracellular water using oxygen isotope ratios of PO ₄

Wang

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Knowledge of the relative contributions of different water sources to intracellular fluids and body water is important for many fields of study, ranging from animal physiology to paleoclimate. The intracellular fluid environment of cells is challenging to study due to the difficulties of accessing and sampling the contents of intact cells. Previous studies of multicelled organisms, mostly mammals, have estimated body water composition-including metabolic water produced as a byproduct of metabolism-based on indirect measurements of fluids averaged over the whole organism (e.g., blood) combined with modeling calculations. In microbial cells and aquatic organisms, metabolic water is not generally considered to be a significant component of intracellular water, due to the assumed unimpeded diffusion of water across cell membranes. Here we show that the 18 O/ 16 O ratio of PO 4 in intracellular biomolecules (e.g., DNA) directly reflects the O isotopic composition of intracellular water and thus may serve as a probe allowing direct sampling of the intracellular environment. We present two independent lines of evidence showing a significant contribution of metabolic water to the intracellular water of three environmentally diverse strains of bacteria. Our results indicate that ∼30-40% of O in PO 4 comprising DNA/biomass in early stationary phase cells is derived from metabolic water, which bolsters previous results and also further suggests a constant metabolic water value for cells grown under similar conditions. These results suggest that previous studies assuming identical isotopic compositions for intracellular/extracellular water may need to be reconsidered. metabolic water | isotope probing | phosphate oxygen isotopes M etabolic water, more precisely defined as an isotopically distinct flux of O (and H) produced during metabolism (1), has been studied extensively as an alternative water source contributing to body water in animals, such as desert mammals, insects, and migrating birds (2-6), but does not easily lend itself to direct measurement. In recent years, interest in metabolic water has been extended to its oxygen isotopic composition ( 18 O/ 16 O ratio or δ 18 O value) and contribution to body water because this information is crucial to the interpretation of biomineral [e.g., carbonate-CaCO 3 -and phosphate-Ca 3 (PO 4 ) 2 ] oxygen isotopic compositions used heavily in paleoclimate/paleohydrological research (7)(8)(9)(10)(11)(12)(13)(14). This includes biomineral shells of aquatic marine organisms that are preserved in the geologic record and used to infer Earth's climate history (15)(16)(17)(18)(19).A core assumption of applications of biomineral oxygen isotopic compositions to infer environmental conditions is that the 18 O: 16 O ratio is controlled by exchange of oxygen isotopes between oxyanions comprising the biomineral and ambient water in bodily fluids (i.e., body water) (9,(20)(21)(22)(23)(24). In multicellular eukaryotic organisms, body water includes all water found in various body compartments (...

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Oxygen isotope signature of UV degradation of glyphosate and phosphonoacetate: Tracing sources and cycling of phosphonates

Sandy

Blake

Chang

et al. 2013

Journal of Hazardous Materials

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Investigation of Compound-Specific Organic-Inorganic Phosphorus Transformation Using Stable Isotope Ratios in Phosphate

Jaisi

Blake

Liang

et al. 2014

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Black carbon pollution of speleothems by fine urban aerosols in tourist caves

Jeong

Kim

Chang

2003

American Mineralogist

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Oxygen isotope, micro-textural and molecular evidence for the role of microorganisms in formation of hydroxylapatite in limestone caves, South Korea

et al. 2010

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Sae Jung Chang

Phosphate oxygen isotopic evidence for a temperate and biologically active Archaean ocean

Precise calibration of equilibrium oxygen isotope fractionations between dissolved phosphate and water from 3 to 37 °C

Archean phosphorus liberation induced by iron redox geochemistry

Probing the metabolic water contribution to intracellular water using oxygen isotope ratios of PO ₄

Oxygen isotope signature of UV degradation of glyphosate and phosphonoacetate: Tracing sources and cycling of phosphonates

Investigation of Compound-Specific Organic-Inorganic Phosphorus Transformation Using Stable Isotope Ratios in Phosphate

Black carbon pollution of speleothems by fine urban aerosols in tourist caves

Oxygen isotope, micro-textural and molecular evidence for the role of microorganisms in formation of hydroxylapatite in limestone caves, South Korea

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Sae Jung Chang

Phosphate oxygen isotopic evidence for a temperate and biologically active Archaean ocean

Precise calibration of equilibrium oxygen isotope fractionations between dissolved phosphate and water from 3 to 37 °C

Archean phosphorus liberation induced by iron redox geochemistry

Probing the metabolic water contribution to intracellular water using oxygen isotope ratios of PO 4

Oxygen isotope signature of UV degradation of glyphosate and phosphonoacetate: Tracing sources and cycling of phosphonates

Investigation of Compound-Specific Organic-Inorganic Phosphorus Transformation Using Stable Isotope Ratios in Phosphate

Black carbon pollution of speleothems by fine urban aerosols in tourist caves

Oxygen isotope, micro-textural and molecular evidence for the role of microorganisms in formation of hydroxylapatite in limestone caves, South Korea

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Resources

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Probing the metabolic water contribution to intracellular water using oxygen isotope ratios of PO ₄