What question did this study set out to answer?

The research aims to dissect the structure and evolution of the RNase MRP complex in humans.

March 28, 2026Open Access

Structural and evolutionary insights into the eukaryotic RNase MRP ribonucleoprotein complex

Puntos clave

The research aims to dissect the structure and evolution of the RNase MRP complex in humans.
Conducted structural analyses using cryo-EM (cryo-electron microscopy).
Utilized structure-based bioinformatics for identifying unique subunits.
Investigated functional roles in precursor-rRNA processing and ribosome assembly.
Identified NEPRO (RMP64) and C18orf21 (RMP24) as unique and essential subunits of RNase MRP.
Described a unique 'double-anchor' substrate-binding mechanism for RNase MRP.
Demonstrated broad substrate specificity due to evolutionary adaptations.

Resumen

Abstract RNase MRP is a conserved eukaryotic ribonucleoprotein essential for precursor-rRNA processing and ribosome assembly. Despite previous studies of yeast RNase MRP, the composition of RNase MRP and how it adapts to process flexible, single-stranded rRNA substrates in most eukaryotes remain enigmatic. Here, we perform an integrative structural, evolutionary, and functional dissection of human RNase MRP. Using structure-based bioinformatics and cryo-EM structural analyses, we identify NEPRO (RMP64) and C18orf21 (RMP24) as the bona fide subunits unique to RNase MRP, which are indispensable for precursor-rRNA cleavage, ribosome assembly, protein synthesis, and chondrogenesis. The structure of human RNase MRP reveals a unique ‘double-anchor’ substrate-binding mechanism that underlies evolutionary adaptations conferring broad substrate specificity. Our work on RNase MRP provides a unified evolutionary and mechanistic framework for this essential ancient ribozyme.

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