A. S. Engel

Microbial contributions to cave formation: New insights into sulfuric acid speleogenesis

The sulfuric acid speleogenesis (SAS) model was introduced in the early 1970s from observations of Lower Kane Cave, Wyoming, and was proposed as a cave-enlargement process due to primarily H 2 S autoxidation to sulfuric acid and subaerial replacement of carbonate by gypsum. Here we present a reexamination of the SAS type locality in which we make use of uniquely applied geochemical and microbiological methods. Little H 2 S escapes to the cave atmosphere, or is lost by abiotic autoxidation, and instead the primary H 2 S loss mechanism is by subaqueous sulfur-oxidizing bacterial communities that consume H 2 S. Filamentous “ Epsilonproteobacteria ” and Gammaproteobacteria , characterized by fluorescence in situ hybridization, colonize carbonate surfaces and generate sulfuric acid as a metabolic byproduct. The bacteria focus carbonate dissolution by locally depressing pH, compared to bulk cave waters near equilibrium or slightly supersaturated with calcite. These findings show that SAS occurs in subaqueous environments and potentially at much greater phreatic depths in carbonate aquifers, thereby offering new insights into the microbial roles in subsurface karstification.

Micro-organisms and earth systems – advances in geomicrobiology: Role of micro-organisms in karstification

INTRODUCTION Whilst chemolithoautotrophic micro-organisms are found in nearly every environment on Earth, they are more abundant in dark habitats where competition by photosynthetic organisms is eliminated. Caves, particularly, represent dark but accessible subsurface habitats where the importance of microbial chemolithoautotrophy to biogeochemical and geological processes can be examined directly. At Lower Kane Cave, WY, USA, hydrogen sulfide-rich springs provide a rich energy source for chemolithoautotrophic micro-organisms, supporting a surprisingly complex consortium of micro-organisms, dominated by sulfur-oxidizing bacteria. Several evolutionary lineages within the class ‘ Epsilonproteobacteria ’ dominate the biovolume of subaqueous microbial mats, and these microbes support the cave ecosystem through chemolithoautotrophic carbon fixation. The anaerobic interior of the cave microbial mats is a habitat for anaerobic metabolic guilds, dominated by sulfate-reducing and -fermenting bacteria. Biological controls of speleogenesis had not been considered previously and it was found that cycling of carbon and sulfur through the different microbial groups directly affects sulfuric acid speleogenesis and accelerates limestone dissolution. This new recognition of the contribution of microbial processes to geological processes provides a better understanding of the causal factors for porosity development in sulfidic groundwater systems. Karst landscapes form where soluble carbonate rocks dissolve by chemical solution (karstification), resulting in numerous geomorphic features, including caves and subterranean-conduit drainage systems (e.g. White, 1988; Ford & Williams, 1989). This has traditionally been viewed as an abiotic, chemical process that occurs near the water table, with biologically produced CO 2 as the principal reactive component.