Detection of archaeal- and prokaryotic-like ribosome exit tunnels within eukaryotic kingdoms

The ribosome exit tunnel is a critical sub-compartment that actively regulates the folding and dynamics of nascent polypeptide chains during protein translation. In this study, we systematically examined tunnel structures of 762 ribosome models obtained through cryo-EM and X-ray crystallography, to quantify structural variations across different species and biological domains. Hierarchical clustering revealed significant geometric differences between prokaryotic and eukaryotic ribosomes, with a surprising discovery: six eukaryotic protist species display tunnel structures remarkably similar to those of archaea and prokaryotes. By analyzing the sequences and structures of ribosomal components forming the tunnel walls, we identified four specific sequence modifications in ribosomal proteins and ribosomal RNAs (rRNA) responsible for these unique geometric variations, and detected these modifications in additional protist species lacking existing 3D structural data. Overall, our findings highlights some complex evolutionary mechanisms governing ribosomal protein and large subunit rRNA, providing novel insights into the tunnel’s regulatory role in protein translation.