Adaptive response of prokaryotic communities to extreme pollution flooding in a Paleolithic rock art cave (Pindal Cave, northern Spain)

A flood event affecting Pindal Cave, a UNESCO World Heritage site, introduced a substantial amount of external sediments and waste into the cave. This event led to the burial of preexisting sediments, altering the biogeochemical characteristics of the cave ecosystem by introducing heightened levels...

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Veröffentlicht in:The Science of the total environment 2024-04, Vol.921, p.171137-171137, Article 171137
Hauptverfasser: Martin-Pozas, Tamara, Cuezva, Soledad, Fernandez-Cortes, Angel, Gonzalez-Pumariega, Maria, Elez, Javier, Duarte, Elsa, de la Rasilla, Marco, Canaveras, Juan Carlos, Saiz-Jimenez, Cesareo, Sanchez-Moral, Sergio
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Sprache:eng
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Zusammenfassung:A flood event affecting Pindal Cave, a UNESCO World Heritage site, introduced a substantial amount of external sediments and waste into the cave. This event led to the burial of preexisting sediments, altering the biogeochemical characteristics of the cave ecosystem by introducing heightened levels of organic matter, nitrogen compounds, phosphorus, and heavy metals. The sediments included particulate matter and waste from a cattle farm located within the water catchment area of the cavity, along with diverse microorganisms, reshaping the cave microbial community. This study addresses the ongoing influence of a cattle farm on the cave ecosystem and aims to understand the adaptive responses of the underground microbial community to the sudden influx of waste allochthonous material. Here, we show that the flood event had an immediate and profound effect on the cave microbial community, marked by a significant increase in methanogenic archaea, denitrifying bacteria, and other microorganisms commonly associated with mammalian intestinal tracts. Furthermore, our findings reveal that one year after the flood, microorganisms related to the flood decreased, while the increase in inorganic forms of ammonium and nitrate suggests potential nitrification, aligning with increased abundances of corresponding functional genes involved in nitrogen cycling. The results reveal that the impact of pollution was neither recent nor isolated, and it was decisive in stopping livestock activity near the cave. The influence of the cattle farm has persisted since its establishment over the impluvium area, and this influence endures even a year after the flood. Our study emphasizes the dynamic interplay between natural events, anthropogenic activities, and microbial communities, offering insights into the resilience of cave ecosystems. Understanding microbial adaptation in response to environmental disturbances, as demonstrated in this cave ecosystem, has implications for broader ecological studies and underscores the importance of considering temporal dynamics in conservation efforts. [Display omitted] •Extreme rainfall and a sinkhole collapse is responsible for abrupt cave disturbance.•Residues from livestock farming provokes NH4+ and NO3− rise in cave sediments.•Cave flooding by water and sediments changed the subterranean microbial community.•Anaerobic microbes and nitrifying bacteria emerge in cave sediments.•Methanotrophy-related functional groups decrease and methanogenic Archa
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2024.171137