Over the last decades, ribonucleic acids (RNAs) have revolutionized our vision of biology. From being a simple messenger allowing to translate the deoxyribonucleic acid (DNA) genetic information into proteins, RNA is now a central player in biology. Among its numerous functions, RNA can accelerate chemical reactions, regulate genetic information or help in information transfer. RNA has recently been unveiled to the general audience due to Covid vaccines, however, it has been seen as a promising way for designing novel therapies since many years and will likely be the basis of major therapeutic breakthroughs in the next decades.
Despite the major fundamental and practical interest for RNA, the understanding of this molecule at the atomic level remains limited. How does an RNA structure itself? How does it move? Are RNA motions important and in which way for its biological function or for designing biotherapies?
Those questions are of major interests for the society. Among the three large classes of biomolecules (DNA, RNA and proteins) RNA remain the least understood. Looking back at the study of proteins, the fundamental understanding of those systems has paved the way of structural biology, allowing for the development of innovative therapies or for various bioengineering advances. Similarly, understanding the fundamental properties of DNA was a major leap forward, providing the molecular rational for heredity, and leading to the development of modern genomic and its numerous applications. The fundamental understanding of RNA is expected to provide as important, yet unknown, discoveries and applications.
If the current progress of biology is sketching RNA importance and functional diversity, the understanding of this key molecule in terms of physical chemistry is still lagging. One of the fundamental reasons explaining this delay, reside in the intrinsic difficulties in working with RNA and observing them at atomic resolution. The objective of the project is to develop a novel strategy based on Nuclear Magnetic Resonance (NMR) to unravel at an unprecedented level of detail the molecular flexibility of RNA molecules. This methodology will be first used to better understand the molecular basis of gene regulation by RNA before being used on various essential RNA. This would thus help in the fundamental understanding of RNA physical chemistry and its connection with RNA function.