The BIOSTASIS project revolved around the study of anhydrobiosis in a tardigrade species ie. Ramazzottius varieornatus. Anhydrobiosis (life without water) is a survival strategy that confers extreme desiccation tolerance. This remarkable phenomenon is present in a limited number of species across the tree of life (animals from four phyla, i.e. Tardigrades, Rotifers, Nematods and Arthropods), selected land plants, certain fungi and bacteria. This strategy is a form of cryptobiosis (latent life), defined by the reversible shut-down of metabolism (biostasis). While desiccated, organisms show no visible signs of life, but they can resume activity in a few minutes to a few hours when placed in a drop of water.
Of all the abiotic environmental stressors, desiccation is considered the most detrimental to organisms. Water availability plays a crucial role in defining individual species activity and their ecological interactions, and organisms are frequently confronted with water shortage in both aquatic and terrestrial ecosystems. The most common drivers of dehydration are the evaporative water loss, freezing during winter (and the subsequent reduction of liquid water in extracellular fluids), and hypersalinity. Global environmental change is expected to greatly affect the magnitude of all of these drivers, impacting life at all hierarchical levels, from genes, to species, to ecosystems.
Genomic studies on anhydrobionts have led to rapid progress on multiple fronts, yet to date, little is known on the relevance of molecules, genes and mechanisms during the entry and the exit of organisms from anhydrobiosis. Within the BIOSTASIS project, using an experimental set up with several time points, I set the ambitious aim to try and reveal key-player genes involved in the mechanism of anhydrobiosis in a strong cryptobiont tardigrade species ie. Ramazzottius varieornatus. My hypothesis: there could be a potential gene signature for anhydrobiosis, establishing a transcription profile that is characteristic of a given physiological state (active, desiccated or rehydrated) and that could possibly reflect the phylogenetic position of a taxon (ie. organisms that are close relatives could have the same transcription profiles).
The project results revealed that the duration of the desiccation stress impacts both the total number of genes that are regulated at the “tun state” and also the recovery time needed for the individuals to return to their normal gene expression levels (as compared to the control samples). The analysed data resulted to new information regarding genes and mechanisms implicated in the mechanisms of anhydrobiosis.