Abstract_EANA2024-23

Abstract EANA2024-23

Hidden Life in Salt City: Astrobiological Studies of Lüneburg's Halophilic Microorganisms

Katharina Runzheimer (1), Yen Ly (1) , Denise Engel (1), Stefan Leuko (1), Michael Laue (2), Katarína Rebrošová (3), Ralf Möller (1)

(1) Institute of Aerospace Medicine, German Aerospace Center (DLR), Germany (2) Robert Koch Institute, Germany (3) Department of Microbiology, Faculty of Medicine, Masaryk University and St. Anne's University Hospital, Brno, Czechia

Introduction

Extreme saline environments, known for their high salt concentrations, have become intriguing focal points for astrobiological research. Despite their harsh and seemingly inhospitable nature, these habitats support a variety of extremophiles. The Lüneburg brine is one such extreme environment, notable for its saturated saline solution that surpasses the salinity of all other European brines. Historically utilized for salt extraction, this brine is easily accessible for sampling. The study of extremophiles from such saline environments is significant as it can offer vital insights into the limits of life on Earth and the potential for life beyond our planet.

Objectives

This research aims to thoroughly characterize the Lüneburg brine in Germany. By employing both cultivation-dependent and independent methods, the study seeks to explore the extreme microbial community and assess the astrobiological relevance of this brine.

Materials and Methods

Extensive sampling of the Lüneburg brine was conducted for this study. The analyses included 16S rRNA amplicon V1-2 and V3-4 sequencing, examination of the cultivable microbial community, and chemical profiling of the brine. Selected microbial isolates were tested for their resistance to astrobiologically relevant stressors including radiation and salts. Microbial pigments were further investigated using Raman spectroscopy.

Findings

16S rRNA amplicon analysis revealed the presence of halophilic archaea with thermophilic, halophilic, and acidophilic representatives. In addition, several yet not cultivated organisms were identified as potential candidates for pure culture isolation. Microscopic examination suggested morphological diversity, with isolates exhibiting pleomorphism. Several cultivated organisms contained the carotenoid bacterioruberin, resulting in red-colored colonies. Isolates investigated revealed a high radiation and salt tolerance, as well as enhanced growth in the usually toxic perchlorates, which are also found on Mars.

Conclusion

The Lüneburg brine, characterized by its saturated saline solution, is an extreme habitat that supports a diverse array of halophilic microorganisms. This study underscores the potential of this accessible habitat for astrobiological research, revealing isolates with various resistances to high salinity, radiation, and other stressors, as well as pleomorphic structures and pigmentation.