AI Article Synopsis
- Bacteria and Eukarya organize their plasma membranes into functional domains, while the unique lipid composition of Archaea creates debate over their membrane structure.
- A novel prediction suggests that in hyperthermophilic Archaea, monolayer and bilayer domains may segregate, allowing distinct membrane proteins to function differently.
- Analysis of Thermococcales species reveals they all produce a mix of diether and tetraether lipids, indicating that domain formation is a common capability among Archaea, potentially dating back to the early evolution of life.
Article Abstract
Bacteria and Eukarya organize their plasma membrane spatially into domains of distinct functions. Due to the uniqueness of their lipids, membrane functionalization in Archaea remains a debated area. A novel membrane ultrastructure predicts that monolayer and bilayer domains would be laterally segregated in the hyperthermophilic archaeon . With very different physico-chemical parameters of the mono- and bilayer, each domain type would thus allow the docking of different membrane proteins and express different biological functions in the membrane. To estimate the ubiquity of this putative membrane ultrastructure in and out of the order Thermococcales, we re-analyzed the core lipid composition of all the Thermococcales type species and collected all the literature data available for isolated archaea. We show that all species of Thermococcales synthesize a mixture of diether bilayer forming and tetraether monolayer forming lipids, in various ratio from 10 to 80% diether in and , respectively. Since the domain formation prediction rests only on the coexistence of di- and tetraether lipids, we show that all Thermococcales have the ability for domain formation, i.e., differential functionalization of their membrane. Extrapolating this view to the whole Archaea domain, we show that almost all archaea also have the ability to synthesize di- and tetraether lipids, which supports the view that functionalized membrane domains may be shared between all Archaea. Hence domain formation and membrane compartmentalization may have predated the separation of the three domains of life and be essential for the cell cycle.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7137397 | PMC |
| http://dx.doi.org/10.3389/fmicb.2020.00526 | DOI Listing |
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