What question did this study set out to answer?

To explore how individual RNA conformations affect function during their formation process.

March 22, 2026Open Access

Functional characterization of dynamic nascent RNA folding ensembles in real time

Key Points

To explore how individual RNA conformations affect function during their formation process.
Utilized multicolor single-molecule fluorescence microscopy experiments.
Tracked nascent RNA structure formation in real time.
Characterized eight different types of RNA molecules.
Investigated the role of ribosomal proteins and RNA modification enzymes in RNA folding.
Identified specific modulation of RNA folding classes by ribosomal proteins and modification enzymes.
Demonstrated a correlation between local RNA accessibility and ribosomal protein chaperoning activity during assembly.
Established a framework for studying RNA folding dynamics and misfolding in relation to function.

Abstract

RNA structure starts forming cotranscriptionally as the nascent RNA emerges from the RNA polymerase and is dynamically modulated by cellular factors. How individual RNA conformations, out of an ensemble of RNA molecules, relate to function is not well understood. Here, developing multicolor single-molecule fluorescence microscopy experiments, we track in real time nascent RNA structure formation, functionally characterizing up to eight different types of RNA molecules. We find that ribosomal proteins, RNA modification enzymes or antisense oligonucleotides specifically modulate a subset of the RNA folding classes. For example, we provide direct evidence that increased local RNA accessibility at specific sites correlates with the chaperoning activity of ribosomal proteins during ribosome assembly. These experiments provide a general framework to study how dynamic RNA folding, and misfolding, relates to function.

Functional characterization of dynamic nascent RNA folding ensembles in real time

Key Points

Abstract

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