RT Journal Article
SR Electronic
T1 The adaptive role of cell death in yeast communities stressed with macrolide antifungals
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 2021.08.27.457932
DO 10.1101/2021.08.27.457932
A1 N. Kireeva
A1 S.S. Sokolov
A1 E.A. Smirnova
A1 K.V. Galkina
A1 F.F. Severin
A1 D.A. Knorre
YR 2021
UL http://biorxiv.org/content/early/2021/08/28/2021.08.27.457932.abstract
AB Microorganisms cooperate with each other to protect themselves from environmental stressors. An extreme case of such cooperation is regulated cell death for the benefit of other cells. Dying cells can provide surviving cells with nutrients or induce their stress-response by transmitting an alarm signal; however, the role of dead cells in microbial communities is unclear. Here we searched for types of stressors the protection from which can be achieved by death of a subpopulation of cells. Thus, we compared the survival of Saccharomyces cerevisiae cells upon exposure to various stressors in the presence of additionally supplemented living versus dead cells. We found that dead cells contribute to yeast community resistance against macrolide antifungals (e.g. amphotericin B [AmB] and filipin) to a greater extent than living cells. Dead yeast cells absorbed more macrolide filipin than control cells because they exposed intracellular sterol-rich membranes. We also showed that, upon the addition of lethal concentrations of AmB, supplementation with AmB-sensitive cells but not with AmB-resistant cells enabled the survival of wild-type cells. Together, our data suggests that cell-to-cell heterogeneity in sensitivity to AmB can be an adaptive mechanism helping yeast communities to resist macrolides, which are naturally occurring antifungal agents.Importance Eukaryotic microorganisms harbour elements of programmed cell death (PCD) mechanisms that are homologous to the PCD of multicellular metazoa. However, it is still debated whether microbial PCD has an adaptive role or the processes of cell death are an aimless operation in self-regulating molecular mechanisms. Here, we demonstrated that dying yeast cells provide an instant benefit for their community by absorbing macrolides, which are bacteria-derived antifungals. Our results illustrate the principle that the death of a microorganism can contribute to the survival of its kin and suggest that early plasma membrane permeabilization improves community-level protection. The latter makes a striking contrast to the manifestations of apoptosis in higher eukaryotes, the process by which plasma membranes maintain integrity.Competing Interest StatementThe authors have declared no competing interest.