Abstract
Despite the unique physiology and metabolic pathways of microbiomes from cold environments providing key evolutionary insights and promising leads for discovering new bioactive compounds, cultivable bacteria entrapped in perennial ice from caves remained a largely unexplored life system. In this context, we obtained and characterized bacterial strains from 13,000-years old ice core of Scarisoara Ice Cave, providing first isolates from perennial ice accumulated in caves since Late Glacial, and first culture-based evidences of bacterial resistome and antimicrobial compounds production. The 68 bacterial isolates belonged to 4 phyla, 34 genera and 56 species, with 17 strains representing putative new taxa. The Gram-negative cave bacteria (Proteobacteria and Bacteroidetes) were more resistant to the great majority of antibiotic classes than the Gram-positive ones (Actinobacteria, Firmicutes). More than 50% of the strains exhibited high resistance to 17 classes of antibiotics. Some of the isolates inhibited the growth of clinically important Gram-positive and Gram-negative resistant strains and revealed metabolic features with applicative potential. The current report on bacterial strains from millennia-old cave ice revealed promising candidates for studying the evolution of environmental resistome and for obtaining new active biomolecules for fighting the antibiotics crisis, and valuable cold-active biocatalysts.
Highlights
Despite the unique physiology and metabolic pathways of microbiomes from cold environments providing key evolutionary insights and promising leads for discovering new bioactive compounds, cultivable bacteria entrapped in perennial ice from caves remained a largely unexplored life system
Amongst strains with identical 16S rRNA amplicon sequence, SC51B.2 and SC14F.2 exhibited different growth temperature intervals (Supplementary Table S1), and Microbacterium hydrocarbonoxydans, Microbacterium pygmaeum and Chryseobacterium hominis isolates differed by their antibiotic susceptibility profiles (Supplementary Table S3)
In addition to our previous reports on cultivable bacteria from ice layers formed during the last 900-years in Scarisoara ice c ave[21,22], the current study adds to the knowledge on functional characteristics of isolated bacteria from this underground perennial ice core
Summary
Despite the unique physiology and metabolic pathways of microbiomes from cold environments providing key evolutionary insights and promising leads for discovering new bioactive compounds, cultivable bacteria entrapped in perennial ice from caves remained a largely unexplored life system. Cold-adapted microbiomes are very important for the global ecology, while their biological activities maintain the nutrient flux in the environment and contribute to the global biogeochemical cycles, being sensitive indicators of climate c hanges[3] Their unique physiology and metabolic pathways provide essential knowledge for understanding the adaptation mechanisms to low temperatures and a valuable source of biomolecules for biotechnological applications. The distribution of the total and putatively active bacterial and fungal communities appeared to be modeled by the climatic characteristics during ice deposition and the organic carbon content of the ice s ubstrate[18,22,24,28,29]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
