Your search keyword '"Iwahana, Go"' showing total 7 results

1. Modeled energetics of bacterial communities in ancient subzero brines.

Author

Kanaan, Georges, Hoehler, Tori M., Iwahana, Go, and Deming, Jody W.

Subjects

BACTERIAL communities, DISSOLVED organic matter, SALT, BOREHOLES, COLLOIDAL carbon, EXTRACELLULAR enzymes, BIOFILMS, ECOSYSTEMS

Abstract

Cryopeg brines are isolated volumes of hypersaline water in subzero permafrost. The cryopeg system at Utqiaġvik, Alaska, is estimated to date back to 40 ka BP or earlier, a remnant of a late Pleistocene Ocean. Surprisingly, the cryopeg brines contain high concentrations of organic carbon, including extracellular polysaccharides, and high densities of bacteria. How can these physiologically extreme, old, and geologically isolated systems support such an ecosystem? This study addresses this question by examining the energetics of the Utqiaġvik cryopeg brine ecosystem. Using literature-derived assumptions and new measurements on archived borehole materials, we first estimated the quantity of organic carbon when the system formed. We then considered two bacterial growth trajectories to calculate the lower and upper bounds of the cellspecific metabolic rate of these communities. These bounds represent the first community estimates of metabolic rate in a subzero hypersaline environment. To assess the plausibility of the different growth trajectories, we developed a model of the organic carbon cycle and applied it to three borehole scenarios. We also used dissolved inorganic carbon and nitrogen measurements to independently estimate the metabolic rate. The model reconstructs the growth trajectory of the microbial community and predicts the present-day cell density and organic carbon content. Model input included measured rates of the in-situ enzymatic conversion of particulate to dissolved organic carbon under subzero brine conditions. A sensitivity analysis of model parameters was performed, revealing an interplay between growth rate, cell-specific metabolic rate, and extracellular enzyme activity. This approach allowed us to identify plausible growth trajectories consistent with the observed bacterial densities in the cryopeg brines. We found that the cell-specific metabolic rate in this system is relatively high compared to marine sediments. We attribute this finding to the need to invest energy in the production of extracellular enzymes, for generating bioavailable carbon from particulate organic carbon, and the production of extracellular polysaccharides for cryoprotection and osmoprotection. These results may be relevant to other isolated systems in the polar regions of Earth and to possible ice-bound brines on worlds such as Europa, Enceladus, and Mars. [ABSTRACT FROM AUTHOR]

Published

2024

2. The ABoVE L-band and P-band Airborne SAR Surveys.

Author

Miller, Charles E., Griffith, Peter C., Hoy, Elizabeth, Pinto, Naiara S., Yunling Lou, Hensley, Scott, Chapman, Bruce D., Baltzer, Jennifer, Bakian-Dogaheh, Kazem, Bolton, W. Robert, Bourgeau-Chavez, Laura, Chen, Richard H., Byung-Hun Choe, Clayton, Leah, Douglas, Thomas A., French, Nancy, Holloway, Jean E., Gang Hong, Lingcao Huang, and Iwahana, Go

Subjects

TUNDRAS, SYNTHETIC aperture radar, TAIGAS, PERMAFROST ecosystems, SOIL depth, FOREST canopies, SOIL moisture

Abstract

Permafrost-affected ecosystems of the Arctic-boreal zone in northwestern North America are undergoing profound transformation due to rapid climate change. NASA's Arctic Boreal Vulnerability Experiment (ABoVE) is investigating characteristics that make these ecosystems vulnerable or resilient to this change. ABoVE employs airborne synthetic aperture radar (SAR) as a powerful tool to characterize tundra, taiga, peatlands, and fens. Here, we present an annotated guide to the L-band and P band airborne SAR data acquired during the 2017, 2018, 2019, and 2022 ABoVE airborne campaigns. We summarize the ~80 SAR flight lines and how they fit into the ABoVE experimental design. We provide hyperlinks to extensive maps, tables, and every flight plan as well as individual flight lines. We illustrate the interdisciplinary nature of airborne SAR data with examples of preliminary results from ABoVE studies including: boreal forest canopy structure from tomoSAR data over Delta Junction, AK and the BERMS site in northern Saskatchewan and active layer thickness and soil moisture data product validation. This paper is presented as a guide to enable interested readers to fully explore the ABoVE L55 and P-band SAR data. [ABSTRACT FROM AUTHOR]

Published

2023

3. Modeled energetics of bacterial communities in ancient subzero brines.

Author

Kanaan, Georges, Hoehler, Tori M., Iwahana, Go, and Deming, Jody W.

Subjects

BACTERIAL communities, DISSOLVED organic matter, BOREHOLES, SALT, COLLOIDAL carbon, EXTRACELLULAR enzymes, BIOFILMS, ECOSYSTEMS

Abstract

Cryopeg brines are isolated volumes of hypersaline water in subzero permafrost. The cryopeg system at Utqiaġvik, Alaska, is estimated to date back to 40  ka BP or earlier, a remnant of a late Pleistocene Ocean. Surprisingly, the cryopeg brines contain high concentrations of organic carbon, including extracellular polysaccharides, and high densities of bacteria. How can these physiologically extreme, old, and geologically isolated systems support such an ecosystem? This study addresses this question by examining the energetics of the Utqiaġvik cryopeg brine ecosystem. Using literature-derived assumptions and new measurements on archived borehole materials, we first estimated the quantity of organic carbon when the system formed. We then considered two bacterial growth trajectories to calculate the lower and upper bounds of the cellspecific metabolic rate of these communities. These bounds represent the first community estimates of metabolic rate in a subzero hypersaline environment. To assess the plausibility of the different growth trajectories, we developed a model of the organic carbon cycle and applied it to three borehole scenarios. We also used dissolved inorganic carbon and nitrogen measurements to independently estimate the metabolic rate. The model reconstructs the growth trajectory of the microbial community and predicts the present-day cell density and organic carbon content. Model input included measured rates of the in-situ enzymatic conversion of particulate to dissolved organic carbon under subzero brine conditions. A sensitivity analysis of model parameters was performed, revealing an interplay between growth rate, cell-specific metabolic rate, and extracellular enzyme activity. This approach allowed us to identify plausible growth trajectories consistent with the observed bacterial densities in the cryopeg brines. We found that the cell-specific metabolic rate in this system is relatively high compared to marine sediments. We attribute this finding to the need to invest energy in the production of extracellular enzymes, for generating bioavailable carbon from particulate organic carbon, and the production of extracellular polysaccharides for cryoprotection and osmoprotection. These results may be relevant to other isolated systems in the polar regions of Earth and to possible ice-bound brines on worlds such as Europa, Enceladus, and Mars. [ABSTRACT FROM AUTHOR]

Published

2023

4. Permafrost ice caves: an unrecognized microhabitat for Arctic wildlife.

Author

Glass, Thomas W., Breed, Greg A., Iwahana, Go, Kynoch, Matthew C., Robards, Martin D., Williams, Cory T., and Kielland, Knut

Subjects

TUNDRAS, CAVES, PERMAFROST, ECOLOGICAL niche, CAVING, ICE

Abstract

Keywords: Arctic; cave; climate change; microhabitat; permafrost; thermokarst; wolverine EN Arctic cave climate change microhabitat permafrost thermokarst wolverine 1 4 4 05/05/21 20210501 NES 210501 The Arctic is changing rapidly, introducing new challenges and opportunities for animals. The first site (Cave A) was used once (April 5) by a single wolverine for 12 h, and the second site (Cave B, 37 km from Cave A) was used twice (April 15 and May 3) by the same wolverine for 1-3 h during each visit. Abundant wolverine scat was present in the vicinity of the cave entrance, including in the trench, suggesting that the wolverines used both the cave and the snowdrifts formed in the trench for their den. Arctic, cave, climate change, microhabitat, permafrost, thermokarst, wolverine. [Extracted from the article]

Published

2021

5. Mapping simulated circum-Arctic organic carbon, ground ice, and vulnerability of ice-rich permafrost to degradation.

Author

Saito, Kazuyuki, Machiya, Hirokazu, Iwahana, Go, Ohno, Hiroshi, and Yokohata, Tokuta

Subjects

EARTH system science, PERMAFROST, CARBON in soils, DIGITAL elevation models, ICE, HISTOSOLS

Abstract

Permafrost is a large reservoir of soil organic carbon, accounting for about half of all the terrestrial storage, almost equivalent to twice the atmospheric carbon storage. Hence, permafrost degradation under global warming may induce a release of a substantial amount of additional greenhouse gases, leading to further warming. In addition to gradual degradation through heat conduction, the importance of abrupt thawing or erosion of ice-rich permafrost has recently been recognized. Such ice-rich permafrost has evolved over a long timescale (i.e., tens to hundreds of thousands of years). Although important, knowledge on the distribution of vulnerability to degradation, i.e., location and stored amount of ground ice and soil carbon in ice-rich permafrost, is still limited largely due to the scarcity of accessible in situ data. Improving the future projections for the Arctic using the Earth System Models will lead to a better understanding of the current vulnerability distribution, which is a prerequisite for conducting climatic and biogeochemical assessment that currently constitutes a large source of uncertainty. In this study, present-day circum-Arctic distributions (north of 50° N) in ground ice and organic soil carbon content are produced by a new approach to combine a newly developed conceptual carbon-ice balance model, and a downscaling technique with the topographical and hydrological information derived from a high-resolution digital elevation model (ETOPO1). The model simulated the evolution of ground ice and carbon for the recent 125 thousand years (from the Last Interglacial to the present) at 1° resolution. The 0.2° high-resolution circum-Arctic maps of the present-day ground ice and soil organic carbon, downscaled from the 1° simulations, were reasonable compared to the observation-based previous maps. These data, together with a map of vulnerability of ice-rich permafrost to degradation served as initial and boundary condition data for model improvement and the future projection of additional greenhouse gas release potentially caused by permafrost degradation. [ABSTRACT FROM AUTHOR]

Published

2020

6. Future projection of greenhouse gas emissions due to permafrost degradation using a simple numerical scheme with a global land surface model.

Author

Yokohata, Tokuta, Saito, Kazuyuki, Ito, Akihiko, Ohno, Hiroshi, Tanaka, Katsumasa, Hajima, Tomohiro, and Iwahana, Go

Subjects

PERMAFROST, GREENHOUSE gases, ATMOSPHERIC temperature, TUNDRAS, CLIMATE change, LAND degradation, SURFACE temperature

Abstract

The Yedoma layer, a permafrost layer containing a massive amount of underground ice in the Arctic regions, is reported to be rapidly thawing. In this study, we develop the Permafrost Degradation and Greenhouse gasses Emission Model (PDGEM), which describes the thawing of the Arctic permafrost including the Yedoma layer due to climate change and the greenhouse gas (GHG) emissions. The PDGEM includes the processes by which high-concentration GHGs (CO2 and CH4) contained in the pores of the Yedoma layer are released directly by dynamic degradation, as well as the processes by which GHGs are released by the decomposition of organic matter in the Yedoma layer and other permafrost. Our model simulations show that the total GHG emissions from permafrost degradation in the RCP8.5 scenario was estimated to be 31-63 PgC for CO2 and 1261-2821 TgCH4 for CH4 (68th percentile of the perturbed model simulations, corresponding to a global average surface air temperature change of 0.05–0.11 °C), and 14-28 PgC for CO2 and 618-1341 TgCH4 for CH4 (0.03–0.07 °C) in the RCP2.6 scenario. GHG emissions resulting from the dynamic degradation of the Yedoma layer were estimated to be less than 1% of the total emissions from the permafrost in both scenarios, possibly because of the small area ratio of the Yedoma layer. An advantage of PDGEM is that geographical distributions of GHG emissions can be estimated by combining a state-of-the-art land surface model featuring detailed physical processes with a GHG release model using a simple scheme, enabling us to consider a broad range of uncertainty regarding model parameters. In regions with large GHG emissions due to permafrost thawing, it may be possible to help reduce GHG emissions by taking measures such as restraining land development. [ABSTRACT FROM AUTHOR]

Published

2020

7. Distinctive microbial communities in subzero hypersaline brines from Arctic coastal sea ice and rarely sampled cryopegs.

Author

Cooper ZS, Rapp JZ, Carpenter SD, Iwahana G, Eicken H, and Deming JW

Subjects

Alaska, Arctic Regions, Bacteria genetics, Bacteria isolation & purification, Cold Temperature, Microbiota, Phylogeny, RNA, Ribosomal, 16S genetics, Salinity, Salts, Temperature, Bacteria classification, Ice Cover microbiology, Permafrost microbiology, Seawater microbiology

Abstract

Hypersaline aqueous environments at subzero temperatures are known to be inhabited by microorganisms, yet information on community structure in subzero brines is very limited. Near Utqiaġvik, Alaska, we sampled subzero brines (-6°C, 115-140 ppt) from cryopegs, i.e. unfrozen sediments within permafrost that contain relic (late Pleistocene) seawater brine, as well as nearby sea-ice brines to examine microbial community composition and diversity using 16S rRNA gene amplicon sequencing. We also quantified the communities microscopically and assessed environmental parameters as possible determinants of community structure. The cryopeg brines harbored surprisingly dense bacterial communities (up to 108 cells mL-1) and millimolar levels of dissolved and particulate organic matter, extracellular polysaccharides and ammonia. Community composition and diversity differed between the two brine environments by alpha- and beta-diversity indices, with cryopeg brine communities appearing less diverse and dominated by one strain of the genus Marinobacter, also detected in other cold, hypersaline environments, including sea ice. The higher density and trend toward lower diversity in the cryopeg communities suggest that long-term stability and other features of a subzero brine are more important selective forces than in situ temperature or salinity, even when the latter are extreme., (© FEMS 2019.)

Published

2019