Structure of a low-population binding intermediate in protein-RNA recognition

Significance All biochemical reactions in living organisms require molecular recognition events. In particular, the interactions between protein and RNA molecules are crucial in the regulation of gene expression. However, the transient nature of the conformations populated during the recognition process has prevented a detailed characterization of the mechanisms by which these interactions take place. To address this problem, we report a high-resolution structure of an intermediate state in protein-RNA recognition. We determined this structure by using NMR measurements as ensemble-averaged structural restraints in metadynamics simulations, and validated it by performing a structure-based design of two mutants with rationally modified binding rates. The interaction of the HIV-1 protein transactivator of transcription (Tat) and its cognate transactivation response element (TAR) RNA transactivates viral transcription and represents a paradigm for the widespread occurrence of conformational rearrangements in protein-RNA recognition. Although the structures of free and bound forms of TAR are well characterized, the conformations of the intermediates in the binding process are still unknown. By determining the free energy landscape of the complex using NMR residual dipolar couplings in replica-averaged metadynamics simulations, we observe two low-population intermediates. We then rationally design two mutants, one in the protein and another in the RNA, that weaken specific nonnative interactions that stabilize one of the intermediates. By using surface plasmon resonance, we show that these mutations lower the release rate of Tat, as predicted. These results identify the structure of an intermediate for RNA-protein binding and illustrate a general strategy to achieve this goal with high resolution.

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