Life without light: microbial diversity and evidence of sulfur- and ammonium-based chemolithotrophy in Movile Cave

Chen, Yin; Wu, Liqin; Boden, Rich; Hillebrand, Alexandra; Kumaresan, Deepak; Moussard, Hélène; Baciu, Mihai; Lu, Yahai; Murrell, J. Colin

doi:10.1038/ismej.2009.57

Cited by 179 publications

(161 citation statements)

References 34 publications

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“…Avenues for understanding alternate non-photosynthetic primary production strategies are limited to subterranean or deep-sea ecosystems that function in the absence of sunlight. A significant amount of research has been devoted to characterizing primary production in ecosystems such as hydrothermal vents (reviewed by Nakagawa and Takai, 2008) and sulfidic caves (Sarbu et al, 1996;Chen et al, 2009;Engel et al, 2010;Jones et al, 2012), where supplies of reduced sulfur, hydrogen or methane support rich chemolithoautotophic activity; however, the energy dynamics of carbonate caves are less well defined. Carbonate cave communities are presumed to be sustained by allocthonous carbon sourced from photic surface ecosystems and entering the cave with vadose-zone drip water, surface water flow or the behavior of macrofauna (Laiz et al, 1999;Simon et al, 2003;Barton et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

Making a living while starving in the dark: metagenomic insights into the energy dynamics of a carbonate cave

et al. 2013

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Carbonate caves represent subterranean ecosystems that are largely devoid of phototrophic primary production. In semiarid and arid regions, allochthonous organic carbon inputs entering caves with vadose-zone drip water are minimal, creating highly oligotrophic conditions; however, past research indicates that carbonate speleothem surfaces in these caves support diverse, predominantly heterotrophic prokaryotic communities. The current study applied a metagenomic approach to elucidate the community structure and potential energy dynamics of microbial communities, colonizing speleothem surfaces in Kartchner Caverns, a carbonate cave in semiarid, southeastern Arizona, USA. Manual inspection of a speleothem metagenome revealed a community genetically adapted to low-nutrient conditions with indications that a nitrogen-based primary production strategy is probable, including contributions from both Archaea and Bacteria. Genes for all six known CO 2 -fixation pathways were detected in the metagenome and RuBisCo genes representative of the Calvin-Benson-Bassham cycle were over-represented in Kartchner speleothem metagenomes relative to bulk soil, rhizosphere soil and deep-ocean communities. Intriguingly, quantitative PCR found Archaea to be significantly more abundant in the cave communities than in soils above the cave. MEtaGenome ANalyzer (MEGAN) analysis of speleothem metagenome sequence reads found Thaumarchaeota to be the third most abundant phylum in the community, and identified taxonomic associations to this phylum for indicator genes representative of multiple CO 2 -fixation pathways. The results revealed that this oligotrophic subterranean environment supports a unique chemoautotrophic microbial community with potentially novel nutrient cycling strategies. These strategies may provide key insights into other ecosystems dominated by oligotrophy, including aphotic subsurface soils or aquifers and photic systems such as arid deserts.

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Section: Introductionmentioning

confidence: 99%

Making a living while starving in the dark: metagenomic insights into the energy dynamics of a carbonate cave

et al. 2013

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“…Among the eight Crenarchaeota OTUs, three were grouped with soil archaea, one was related to the Nitrosocaldus genus, and four were archaea from a marine environ- ment. The Euryarchaeota and Creanarchaeota taxa are dominant in archaea communities in limestone caves (Chelius and Moore, 2004;Chen et al, 2009), including Crenarchaeota from marine environments that have previously been found in caves (Chelius and Moore, 2004).…”

Section: Resultsmentioning

confidence: 99%

“…These micro-organisms are a monophyletic group of phenotypically diverse prokaryotes. Initially, it was believed that they were found only in extreme environments; however, several articles have demonstrated that archaea probably occur in all environments that support life, including caves (Gonzalez et al, 2006;Chen et al, 2009;Jarrel et al, 2011). This group was found to be important for ecological relationships in several environments, particularly because of their role in biogeochemical cycles (Kudo et al, 1997;Chen et al, 2009;Jarrel et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Organic matter enrichment affects archaea community in limestone cave sediments

Marques¹,

Dias²,

Silva³

et al. 2017

JCKS

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Caves are unique environments filled with complex microbial communities that have adapted to oligotrophy. Communities of fungi and bacteria are commonly studied in touristic caves or are associated with guano or other sources of organic matter, but the archaeal community is often overlooked in these conditions. Based on this gap in the existing literature, the present study aims to evaluate the effect of a unique in vitro contamination event by organic matter in the archaeal community over the course of one year. For that purpose, samples were collected in Gruta Manoel Ioiô, a limestone cave located in Iraquara, Brazil. The collected samples were transported to the laboratory to undergo an enrichment of 0.25% or 0.5% mixture 1:1 (w/w) of yeast and meat extract. Samplings were collected at 0, 1, 6, and 12 months to evaluate the effects on the archaeal community by polymerase chain reaction followed by Denaturing Gel Gradient Electrophoresis (PCR-DGGE). PCR-DGGE profiles show that Operational Taxonomic Units (OTUs) remained in all samples, but variations were observed among the contaminated and control samples, especially at 6 months. Also, an increase in the number of OTUs was observed in samples that received the addition of organic matter in relation to the control. These OTUs were identified as Euryarchaeota and Crenarchaeota. This study showed that the archaeal community could be impacted by organic matter contamination in caves.

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“…En contraste con los ambientes subaéreos dominados por comunidades fotosintéticas, los microbios subterráneos requieren un metabolismo quimiosintético para la productividad primaria, tal vez confinado a la oxidación de compuestos con azufre y hierro (principales fuentes de energía de tales ambientes) para sustentar su crecimiento y continuidad (Sarbu et al, 1996;Chen et al, 2009;Porter et al, 2009). Debido a que estas vías metabólicas son menos energéticas que la fotosíntesis (i.e.…”

Section: Los Ambientes Subterráneosunclassified

La vida temprana en la Tierra y los primeros ecosistemas terrestres

Beraldi-Campesi¹

2014

BSGM

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La vida temprana en la Tierra y los primeros ecosistemas terrestres 65 ResumenLos ecosistemas terrestres han sido considerados tradicionalmente como superficies dominadas por plantas, cuyos primeros registros datan del Fanerozoico temprano (< 550 Ma/millones de años). Sin embargo, la presencia de componentes biológicos mucho más antiguos que las plantas en hábitats tan distintos como suelos, turberas, estanques, lagos, arroyos y dunas, sugiere que los ecosistemas terrestres comenzaron a existir en la Tierra hace al menos 2700 Ma. Los microbios fueron abundantes hace ~3500 Ma y sin duda se adaptaron a vivir en condiciones subaéreas, en entornos intermareales y en zonas áridas y semiáridas, como lo hacen actualmente los microbios terrestres, y que tienen una enorme y rápida capacidad de adaptación a condiciones cambiantes. Todo ello está respaldado por el registro fósil. No obstante, esta evidencia es inusual e indirecta en comparación con fósiles de ambientes marinos, superficiales o profundos, y su registro ha sido poco atendido. En consecuencia, la noción de que fueron comunidades microbianas las que formaron los primeros ecosistemas terrestres no ha sido ampliamente difundido ni incorporado conceptualmente en la sociedad. Hoy conocemos un amplio registro fósil de biota marina somera y lacustre a partir de los ~3500 Ma, así como microbios colonizando ambientes costeros desde hace ~3450 Ma y evidencia indirecta de actividad biológica en paleosuelos de > 3400 Ma de edad. El tipo de ambientes, de donde proviene esta evidencia, sugiere que la vida terrestre se produjo casi en paralelo con la vida acuática en el Arqueano. Las rápidas adaptaciones observadas en microbios actuales, su excepcional tolerancia a condiciones extremas y fluctuantes, su rápida y temprana diversificación y su antiguo registro fósil, indican que los primeros ecosistemas terrestres fueron exclusivamente microbianos. Es factible que los microbios contribuyeran en la formación de los primeros suelos donde las plantas se desarrollaron más tarde. Comprender cómo la vida se diversificó y adaptó a las condiciones terrestres es fundamental para entender su impacto en los sistemas terrestres durante millones de años. Beraldi-Campesi 66 661. Introducción Definición de terrestreLos ambientes terrestres seguramente han existido a través de toda la historia geológica de la Tierra a menos que su superficie estuviera permanentemente bajo el agua, lo cual no es aceptablemente realista. La definición de 'terrestre' no es tan trivial como parece. Aunque aquí se define como un ambiente 'no acuático', la distinción entre lo marino y lo terrestre atraviesa un amplio espectro de ambientes transicionales, donde lo acuático y lo no-acuático evolucionan y superponen en el tiempo. Comúnmente se entiende que un entorno terrestre (sobre el nivel del mar), puede incluir ambientes acuáticos (lagos cubiertos o no de hielo, lagunas y humedales, turberas, ríos y arroyos, campos geotérmicos) y no-acuáticos (especialmente zonas con poca lluvia). Estos hábitats pueden experimen...

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Life without light: microbial diversity and evidence of sulfur- and ammonium-based chemolithotrophy in Movile Cave

Cited by 179 publications

References 34 publications

Making a living while starving in the dark: metagenomic insights into the energy dynamics of a carbonate cave

Making a living while starving in the dark: metagenomic insights into the energy dynamics of a carbonate cave

Organic matter enrichment affects archaea community in limestone cave sediments

La vida temprana en la Tierra y los primeros ecosistemas terrestres

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