ABSTRACT
Ribosomes from different species can markedly differ in their composition by including dozens of ribosomal proteins that are unique to specific lineages but absent in others. However, it remains unknown how ribosomes acquire and specialize new proteins throughout evolution. Here, to help answer this question, we describe the evolution of the ribosomal protein msL1/msL2 that was recently found in ribosomes from the parasitic microorganism clade, microsporidia. We first show that this protein has a conserved location in the ribosome but entirely dissimilar structures in different organisms: in each of the analyzed species, msL1/msL2 exhibits an altered secondary structure, an inverted orientation of the N- and C-termini on the ribosomal binding surface, and a completely transformed three-dimensional fold. We then show that this evolutionary fold switching is likely caused by changes in the msL1/msL2-binding site in the ribosome; specifically, by variations in microsporidian rRNA. These observations allow us to infer an evolutionary scenario in which a small, positively-charged, de novo-born unfolded protein was first captured by rRNA to become part of the ribosome and subsequently underwent complete fold switching to optimize its binding to its evolving ribosomal binding site. Overall, our work provides a striking example of how a protein can switch its fold in the context of a complex biological assembly while retaining its specificity for its molecular partner. This finding will help us better understand the origin and evolution of new protein components of complex molecular assemblies – thereby enhancing our ability to engineer biological molecules, identify protein homologs, and peer into the history of life on Earth.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
We have updated Figures 1, 2 and 3 to improve clarity and show additional analyses of msL1/msL2 conservation. We then added a few additional paragraphs to the introduction and discussion of the manuscript to describe the apparent molecular function of msL1/msL2 and a possible origin of these proteins in microsporidia.