Editorial: Insights in extreme microbiology: 2021 (original) (raw)
Related papers
Effect Of Extreme Environment On Microorganism – Adaptive Mechanisms
Microorganisms not only growing under but requiring unusual, thus extreme, environmental conditions for growth are grouped together under the term extremophiles. They come in all kinds of forms. Many of them cannot even survive under what we call, ‘normal conditions’, i.e. conditions conducive to the human physiology and for most of the microorganisms associated with humans, which are mesophilic neutrophilic microorganisms. Microbes can return to life even after hundreds of millions of years. Furthermore, a variety of studies demonstrate that microorganisms can survive under extreme conditions, such as ultracentrifugation, hypervelocity, shock pressure, high temperature variations, vacuums, and different ultraviolet and ionizing radiation intensities. With these discoveries, our knowledge about the biosphere has grown and the putative boundaries of life have expanded. This present work examines how extreme environment affect microorganism that do not tolerate it.
A Special Issue on Microorganisms from Extreme Environments in Memory of Luigi Michaud (1974–2014)
Diversity
A special issue (SI) titled “Microbial Diversity in Extreme Environments: Implications for Ecological and Applicative Perspectives” has been launched with the aim of showcasing the diversity and biotechnological potential of extremophilic microorganisms. The issue includes 10 research papers and four reviews that mainly address prokaryotes inhabiting hyperarid, hypercold, hyperalkaline and hypersaline (or polyextreme) environments, spanning from deserts to meromictic and glacier lakes around the globe. Thermophilic prokaryotes from shallow hydrothermal vents and Antarctic geothermal soils are also treated. The ecology and biotechnological perspectives of eukaryotes are discussed in two review papers and one research paper. This special issue serves as a memorial to Dr. Luigi Michaud (1974–2014), who dramatically passed away in Antarctica during underwater sampling activities.
Viruses in extreme environments
The tolerance limits of extremophiles in term of temperature, pH, salinity, desiccation, hydrostatic pressure, radiation, anaerobiosis far exceed what can support non-extremophilic organisms. Like all other organisms, extremo-philes serve as hosts for viral replication. Many lines of evidence suggest that viruses could no more be regarded as simple infectious ''fragments of life'' but on the contrary as one of the major components of the biosphere. The exploration of niches with seemingly harsh life conditions as hypersaline and soda lakes, Sahara desert, polar environments or hot acid springs and deep sea hydrothermal vents, permitted to track successfully the presence of viruses. Substantial populations of double-stranded DNA virus that can reach 10 9 particles per milliliter were recorded. All these viral communities, with genome size ranging from 14 kb to 80 kb, seem to be genetically distinct, suggesting specific niche adaptation. Nevertheless, at this stage of the knowledge, very little is known of their origin, activity, or importance to the in situ microbial dynamics. The continuous attempts to isolate and to study viruses that thrive in extreme environments will be needed to address such questions. However, this topic appears to open a new window on an unexplored part of the viral world.
Journal Name: Frontiers in Microbiology
2014
Andersen GL(2014) Temperature and injection water source influence microbial community structure in four Alaskan North Slope hydrocarbon reservoirs.. Front. Microbiol. 5:409. doi:10.3389/fmicb.2014.00409
Journal of biomolecular techniques : JBT, 2017
The Extreme Microbiome Project (XMP) is a project launched by the Association of Biomolecular Resource Facilities Metagenomics Research Group (ABRF MGRG) that focuses on whole genome shotgun sequencing of extreme and unique environments using a wide variety of biomolecular techniques. The goals are multifaceted, including development and refinement of new techniques for the following: 1) the detection and characterization of novel microbes, 2) the evaluation of nucleic acid techniques for extremophilic samples, and 3) the identification and implementation of the appropriate bioinformatics pipelines. Here, we highlight the different ongoing projects that we have been working on, as well as details on the various methods we use to characterize the microbiome and metagenome of these complex samples. In particular, we present data of a novel multienzyme extraction protocol that we developed, called Polyzyme or MetaPolyZyme. Presently, the XMP is characterizing sample sites around the wo...