A mechanical explanation of RNA pseudoknot function in programmed ribosomal frameshifting

Ribosomal frameshifting is a translational mechanism involved in protein synthesis during the replication of many viral pathogens and in cellular genes more generally. A new set of images of an 80S ribosome stalled at an mRNA pseudoknot shows how the pseudoknot manipulates the ribosome into a different reading frame.

Cryoelectron microscopic imaging is used to visualize a translating ribosome stalled during frameshifting.

The triplet-based genetic code requires that translating ribosomes maintain the reading frame of a messenger RNA faithfully to ensure correct protein synthesis ¹ . However, in programmed -1 ribosomal frameshifting ² , a specific subversion of frame maintenance takes place, wherein the ribosome is forced to shift one nucleotide backwards into an overlapping reading frame and to translate an entirely new sequence of amino acids. This process is indispensable in the replication of numerous viral pathogens, including HIV and the coronavirus associated with severe acute respiratory syndrome ³ , and is also exploited in the expression of several cellular genes ⁴ . Frameshifting is promoted by an mRNA signal composed of two essential elements: a heptanucleotide ‘slippery’ sequence ⁵ and an adjacent mRNA secondary structure, most often an mRNA pseudoknot ⁶ . How these components operate together to manipulate the ribosome is unknown. Here we describe the observation of a ribosome–mRNA pseudoknot complex that is stalled in the process of -1 frameshifting. Cryoelectron microscopic imaging of purified mammalian 80S ribosomes from rabbit reticulocytes paused at a coronavirus pseudoknot reveals an intermediate of the frameshifting process. From this it can be seen how the pseudoknot interacts with the ribosome to block the mRNA entrance channel, compromising the translocation process and leading to a spring-like deformation of the P-site transfer RNA. In addition, we identify movements of the likely eukaryotic ribosomal helicase and confirm a direct interaction between the translocase eEF2 and the P-site tRNA. Together, the structural changes provide a mechanical explanation of how the pseudoknot manipulates the ribosome into a different reading frame.