S Ruff, Pauline Humez, Isabella Hrabe de Angelis, Muhe Diao, Michael Nightingale, Sara Cho, Liam Connors, Olukayode Kuloyo, Alan Seltzer, Samuel Bowman, Scott Wankel, Cynthia McClain, Bernhard Mayer, Marc Strous
{"title":"Hydrogen and Dark Oxygen drive Microbial Productivity in diverse Groundwater Ecosystems","authors":"S Ruff, Pauline Humez, Isabella Hrabe de Angelis, Muhe Diao, Michael Nightingale, Sara Cho, Liam Connors, Olukayode Kuloyo, Alan Seltzer, Samuel Bowman, Scott Wankel, Cynthia McClain, Bernhard Mayer, Marc Strous","doi":"10.3897/aca.6.e108163","DOIUrl":null,"url":null,"abstract":"Around 50% of humankind relies on groundwater as a source of drinking water. We investigated the age, geochemistry, and microbiology of 138 groundwater samples from 87 monitoring wells (<250 m depth) located in 14 aquifers in Canada (Fig. 1). Geochemistry and microbiology showed consistent trends suggesting large-scale aerobic and anaerobic hydrogen, methane, nitrogen, and sulfur cycling carried out by diverse microbial communities. Older groundwaters, especially in aquifers with organic carbon-rich strata, contained on average more cells than younger groundwaters, challenging current estimates of subsurface cell abundances. We observed substantial concentrations of dissolved oxygen in older groundwaters that could support aerobic lifestyles in subsurface ecosystems at an unprecedented scale. Metagenomics, oxygen isotope analyses and mixing models indicated that “dark oxygen” was produced in situ via microbial dismutation. We show that ancient groundwaters sustain productive communities and highlight an overlooked oxygen source in present and past subsurface ecosystems of Earth Ruff et al. 2023). Title, Abstract, and Figure 1 are reproduced from (Ruff et al. 2023) without adaptations, according to the terms of http://creativecommons.org/licenses/by/4.0/.","PeriodicalId":101714,"journal":{"name":"ARPHA Conference Abstracts","volume":"9 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2023-10-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"ARPHA Conference Abstracts","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3897/aca.6.e108163","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Around 50% of humankind relies on groundwater as a source of drinking water. We investigated the age, geochemistry, and microbiology of 138 groundwater samples from 87 monitoring wells (<250 m depth) located in 14 aquifers in Canada (Fig. 1). Geochemistry and microbiology showed consistent trends suggesting large-scale aerobic and anaerobic hydrogen, methane, nitrogen, and sulfur cycling carried out by diverse microbial communities. Older groundwaters, especially in aquifers with organic carbon-rich strata, contained on average more cells than younger groundwaters, challenging current estimates of subsurface cell abundances. We observed substantial concentrations of dissolved oxygen in older groundwaters that could support aerobic lifestyles in subsurface ecosystems at an unprecedented scale. Metagenomics, oxygen isotope analyses and mixing models indicated that “dark oxygen” was produced in situ via microbial dismutation. We show that ancient groundwaters sustain productive communities and highlight an overlooked oxygen source in present and past subsurface ecosystems of Earth Ruff et al. 2023). Title, Abstract, and Figure 1 are reproduced from (Ruff et al. 2023) without adaptations, according to the terms of http://creativecommons.org/licenses/by/4.0/.
大约50%的人类依赖地下水作为饮用水的来源。我们研究了来自加拿大14个含水层87口监测井(深度250 m)的138个地下水样本的年龄、地球化学和微生物学(图1)。地球化学和微生物学显示出一致的趋势,表明不同的微生物群落进行了大规模的好氧和厌氧氢、甲烷、氮和硫循环。较老的地下水,特别是在富有机碳地层的含水层中,平均比较年轻的地下水含有更多的细胞,这对目前对地下细胞丰度的估计提出了挑战。我们在古老的地下水中观察到大量的溶解氧,这些溶解氧可以在前所未有的规模上支持地下生态系统中的有氧生活方式。宏基因组学、氧同位素分析和混合模型表明,“暗氧”是通过微生物突变在原位产生的。我们表明,古代地下水维持了生产性群落,并强调了地球现在和过去地下生态系统中被忽视的氧气来源(Ruff等人,2023)。根据http://creativecommons.org/licenses/by/4.0/的条款,标题、摘要和图1摘自(Ruff et al. 2023),未经改编。
求助内容:
应助结果提醒方式:
京公网安备 11010802042870号
