Methanogenic archaea, characterized by their cell membrane
lipid
molecules consisting of isoprenoid chains linked to glycerol-1-phosphate
via ether bonds, exhibit exceptional adaptability to extreme environments.
However, this distinct lipid architecture also complicates the interactions
between methanogenic archaea and nanoparticles. This study addresses
this challenge by exploring the interaction and transformation of
selenium nanoparticles (SeNPs) within archaeal Methanosarcina
acetivorans C2A. We demonstrated that the effects
of SeNPs are highly concentration-dependent, with chemical stimulation
of cellular processes at lower SeNPs concentrations as well as oxidative
stress and metabolic disruption at higher concentrations. Notably,
we observed the formation of a protein corona on SeNPs, characterized
by the selective adsorption of enzymes critical for methylotrophic
methanogenesis and those involved in selenium methylation, suggesting
potential alterations in protein function and metabolic pathways.
Furthermore, the intracellular transformation of SeNPs into both inorganic
and organic selenium species highlighted their bioavailability and
dynamic transformation within archaea. These findings provide vital
insights into the nano-bio interface in archaeal systems, contributing
to our understanding of archaeal catalysis and its broader applications.