Microbial diversity gradients in the geothermal mud volcano underlying the hypersaline Urania Basin

Lazar, Cassandre Sara; Schmidt, Frauke; Elvert, Marcus; Heuer, Verena B; Hinrichs, Kai−Uwe; Teske, Andreas

doi:10.3389/fmicb.2022.1043414

Cited by 3 publications

(3 citation statements)

References 102 publications

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“…[19]. However, the results of this study showed that some vegetation can grow and develop around mud volcanoes.…”

contrasting

confidence: 53%

Mud Volcanoes and Adjacent Vegetation Adaptation in the Rembang Zone, Indonesia: An Approach for Mud Volcano Investigation

Sitinjak,

Harbowo

2024

IOP Conf. Ser.: Earth Environ. Sci.

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The Rembang Zone is a physiographic zone located in the northern part of Java, Indonesia. Rembang zone includes the areas from Rembang to Tuban and reaches the island of Madura. Ten mud volcanoes were identified, each with varying levels of eruptive intensity. Locals have reported that newly erupted mud materials can disrupt soil fertility in the surrounding areas, leading to vegetation death. Interestingly, we discovered several types of vegetation at mud volcano sites that have adapted, survived, and supported vegetation succession in the surrounding areas. Therefore, in this study, we investigated the vegetation around mud volcanoes in the Rembang Zone and its mud characteristics. We employed Sankey diagram analysis to explore the adapted plant taxa at mud volcano sites in the Rembang Zone. Additionally, we assessed the substrate using Scanning Electron Microscopy (SEM) and conducted geochemical analyses on fluid and non-condensable gas using Inductively Coupled Plasma Mass Spectrometry (ICP-MS) and Gas Chromatography Mass Spectrometry (GC-MS). The results of this study reveal that there are at least 10 potential mud volcano sites in the Rembang Zone that could be inhabited by vegetation from the Poaceae family (20%), Asteraceae (18%), Cyperaceae (15%), Fabaceae (13%), Euphorbiaceae (9%), and other plant families (2%). These plants tend to adapt to the mud volcano substrate composed of Fe (0.00-0.35 mg/L), Ca (2.9-0.16%), Na (0.02-23.7%), and Cl (13-74%). This demonstrates that vegetation around mud volcanoes in the Rembang Zone can adapt to high-salinity conditions. SEM observations revealed a high smectite content associated with limestone rock. The mud volcanoes frequently emit gases such as N2 (2.3-73%), CH4 (0-8.8%), and CO2 (17-95%), indicating a tendency to produce substrates with nearly water-boiling temperatures (45-105°C). These findings serve as a reference for further understanding the presence of vegetation around mud volcanoes, particularly for identifying the presence of other mud volcanoes through remote sensing.

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“…[19]. However, the results of this study showed that some vegetation can grow and develop around mud volcanoes.…”

contrasting

confidence: 53%

Mud Volcanoes and Adjacent Vegetation Adaptation in the Rembang Zone, Indonesia: An Approach for Mud Volcano Investigation

Sitinjak,

Harbowo

2024

IOP Conf. Ser.: Earth Environ. Sci.

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“…Particularly, the cryogenic, desiccating Martian conditions, along with the lack of metamorphic activity, might have contributed to biomarker longevity 124 . Corresponding terrestrial environments, which foster active ecosystems, are well-documented to maintain biomarker integrity over substantial geologic timescales 125 – 128 .…”

Section: Discussion On the Significance Of Amazonian Sedimentary Erup...mentioning

confidence: 99%

Exploring the evidence of Middle Amazonian aquifer sedimentary outburst residues in a Martian chaotic terrain

Rodriguez,

Wilhelm,

Travis

et al. 2023

Sci Rep

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The quest for past Martian life hinges on locating surface formations linked to ancient habitability. While Mars' surface is considered to have become cryogenic ~3.7 Ga, stable subsurface aquifers persisted long after this transition. Their extensive collapse triggered megafloods ~3.4 Ga, and the resulting outflow channel excavation generated voluminous sediment eroded from the highlands. These materials are considered to have extensively covered the northern lowlands. Here, we show evidence that a lacustrine sedimentary residue within Hydraotes Chaos formed due to regional aquifer upwelling and ponding into an interior basin. Unlike the northern lowland counterparts, its sedimentary makeup likely consists of aquifer-expelled materials, offering a potential window into the nature of Mars' subsurface habitability. Furthermore, the lake’s residue’s estimated age is ~1.1 Ga (~3.2 Ga post-peak aquifer drainage during the Late Hesperian), enhancing the prospects for organic matter preservation. This deposit’s inferred fine-grained composition, coupled with the presence of coexisting mud volcanoes and diapirs, suggest that its source aquifer existed within abundant subsurface mudstones, water ice, and evaporites, forming part of the region’s extremely ancient (~ 4 Ga) highland stratigraphy. Our numerical models suggest that magmatically induced phase segregation within these materials generated enormous water-filled chambers. The meltwater, originating from varying thermally affected mudstone depths, could have potentially harbored diverse biosignatures, which could have become concentrated within the lake’s sedimentary residue. Thus, we propose that Hydraotes Chaos merits priority consideration in future missions aiming to detect Martian biosignatures.

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“…The distribution of the microbial communities in the deep sea is related to the sediment provenances. 26,27 Although classes Lokiarchaeia, Bathyarchaeia and Nitrososphaeria are common lineages in deep-sea sediments, 28 their varying abundances in different turbidite deposits along the JT (Figure 1B & C) indicate the difference in turbidite sources, 12,29 which is also suggested by the varying OC characteristics (Figure 2A). The abundance of the aerobic Candidatus Nitrosopumilus 30 in T1 and T3 turbidites of GeoB16431 (Figure 1B) indicates that these turbidites are composed of mostly remobilized oxic surficial sediments at the sea floor instead of deep subsurface sediments.…”

Section: Introductionmentioning

confidence: 99%

Earthquake-induced redistribution and reburial of microbes in the hadal trenches

Chu,

Liu,

et al. 2023

TIG

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<p>The hadal trenches located on the subduction zone harbor unique deep-sea microbes, yet the mechanisms regulating the characteristics of the deep-sea microbial communities remain largely unknown. The frequent and unpredictable tectonic processes such as earthquakes triggered by plate subduction act as a lateral transport pathway for sediments, and may lead to redistribution and reburial of allochthonous microbes. However, such tectonically-triggered processes in the hadal trenches are not yet investigated. Here we demonstrate that distinctive allochthonous microbial communities are introduced into the Japan Trench by three historical earthquakes, with community structure transitions observed across the turbidite boundaries. The variations of the microbial community structures are linked to earthquake-driven organic carbon deposition and its characteristics, suggesting the potential impact of mass transport events on the microbial-mediated deep carbon cycles. Our calculations indicate that the Pacific trenches receive at least 5.1 Pg of earthquake-induced microbial biomass carbon during the past century, with spatial and temporal variations at different scales. These results suggest that pulsed tectonic events play a crucial role in introducing allochthonous microbes to the deep biosphere, potentially leading to substantial microbial biomass carbon export into the subduction zone.</p>

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Microbial diversity gradients in the geothermal mud volcano underlying the hypersaline Urania Basin

Cited by 3 publications

References 102 publications

Mud Volcanoes and Adjacent Vegetation Adaptation in the Rembang Zone, Indonesia: An Approach for Mud Volcano Investigation

Mud Volcanoes and Adjacent Vegetation Adaptation in the Rembang Zone, Indonesia: An Approach for Mud Volcano Investigation

Exploring the evidence of Middle Amazonian aquifer sedimentary outburst residues in a Martian chaotic terrain

Earthquake-induced redistribution and reburial of microbes in the hadal trenches

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