Updates on microbial Iodine Cycling in snotty Biofilms of a prealpine Mineral Spring Cavern

ARPHA Conference Abstracts Pub Date : 2023-10-17 DOI:10.3897/aca.6.e108241

Tillmann Lueders, Clemens Karwautz, Barbara Bekwinknoll, Felix Beulig, Baoli Zhu

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Abstract

We have previously described the massive, methane-oxidizing microbial biofilms discovered in the cavern of an iodine-rich former medicinal spring in prealpine southern Germany (Karwautz et al. 2017). Next to up to 3000 ppm of methane in the cavern atmosphere, the mineral spring water can contain up to 23 mM of iodine, ~thousand-fold higher than in natural freshwaters. Since reactive iodine species can be toxic for microbes, the massive microbial growth in this cave is a fascinating phenomenon. We postulate that microbes capable of utilizing different iodine species should be prevalent in the cavern. Here, we present our recent work investigating the possible involvement of biofilm microbiota in either oxidative or reductive iodine cycling. Gradient tubes set up with iodide and oxygen as redox partners showed ample microbial growth and the formation of elemental iodine. Amplicon sequencing suggested different Alpha - ( Magnetospirillum spp.) and Gammaproteobacteria ( Aeromonas spp.) to be capable of iodide oxidation. Moreover, we address a possible iodate-dependent methane oxidation hosted within biofilm microbiota. Metagenomes allowed to assemble the MAGs of a novel member of the recently discovered anaerobic Methylomirabilota methanotrophs, Candidatus Methylomirabilis iodofontis . Its genetic repertoire included not only known markers of oxygenic denitrification and aerobic methane oxidation, but also of iodate respiration (Zhu et al. 2022). Our ongoing work will provide further evidence of the still largely uncharted iodine-cycling ecophysiologies of the biofilm microbiota of this unique microbe-dominated subsurface ecosystem.

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高山前矿泉溶洞流状生物膜微生物碘循环研究进展

我们之前已经描述了在德国南部前高山富含碘的前药用泉的洞穴中发现的大量甲烷氧化微生物生物膜(Karwautz et al. 2017)。在洞穴大气中，除了高达3000 ppm的甲烷外，矿泉水的碘含量可达23毫米，比天然淡水高出数千倍。由于活性碘对微生物是有毒的，所以这个洞穴里大量的微生物生长是一个令人着迷的现象。我们假设能够利用不同碘种的微生物应该在洞穴中普遍存在。在这里，我们介绍了我们最近的工作，研究生物膜微生物群在氧化或还原性碘循环中的可能参与。以碘和氧为氧化还原伙伴的梯度管显示了充足的微生物生长和元素碘的形成。扩增子测序表明不同的α -(磁螺旋藻)和γ -变形菌(气单胞菌)具有氧化碘的能力。此外，我们解决了可能的碘依赖甲烷氧化宿主在生物膜微生物群。宏基因组允许组装最近发现的厌氧甲基化菌中一个新成员的mag，候补甲基化菌。其遗传库不仅包括已知的氧反硝化和有氧甲烷氧化标记，还包括碘酸盐呼吸标记(Zhu et al. 2022)。我们正在进行的工作将为这个独特的以微生物为主的地下生态系统的生物膜微生物群的碘循环生态生理学提供进一步的证据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ARPHA Conference Abstracts

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