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Ribosomal shunting


Ribosome shunting is a mechanism of translation initiation in which ribosomes physically bypass, or shunt over, parts of the 5' untranslated region to reach the initiation codon. This enables viruses to have more information than usual in an mRNA molecule. Some viral RNAs have been shown to use ribosome shunting as a more efficient form of translation during certain stages of viral life cycle or when translation initiation factors are scarce (e.g. cleavage by viral proteases). Some viruses known to use this mechanism include adenovirus, Sendai virus, human papillomavirus, duck hepatitis B pararetrovirus, rice tungro bacilliform viruses, and cauliflower mosaic virus. In these viruses the ribosome is directly translocated from the upstream initiation complex to the start codon (AUG) without the need for eIF4A helicase activity to unwind RNA secondary structures.

Translation of Cauliflower mosaic virus (CaMV) 35S RNA is initiated by a ribosome shunt. The 35S RNA of CaMV contains a ~600nt leader sequence which contains 7-9 short open reading frames (sORFs) depending on the strain. This long leader sequence has the potential to form an extensive complex stem-loop structure, which is an inhibitory element for expression of following ORFs. However, translation of ORFs downstream of the CaMV 35S RNA leader has been commonly observed. Ribosome shunting model indicates with the collaboration of initiation factors, ribosomes start scanning from capped 5’-end and scans for a short distance until it hits the first sORF. The hairpin structure formed by leader brings the first long ORF into the close spatial vicinity of a 5’-proximal sORF. After read through sORF A, the 80S scanning ribosome disassembles at the stop codon, which is the shunt take-off site. The 40S ribosomal subunits keep combining with RNA, and bypass the strong stem-loop structural element, land at the shunt acceptor site, resume scanning and reinitiate at the first long ORF. 5’-proximal sORF A and the stem-loop structure itself are two essential elements for CaMV shunting [5]. sORFs with 2-15 codons, and 5-10 nts between sORF stop codon and the base of the stem structure are optimal for ribosome shunting, while the minimal (start-stop) ORF does not promote shunting.

Ribosome shunting process was first discovered in CaMV in 1993, and then was reported in Rice tungro bacilliform virus (RTBV) at 1996. The mechanism of ribosome shunting in RTBV resembles that in CaMV: it also requires the first short ORF as well as a following strong secondary structure. Swapping of the conserved shunt elements between CaMV and RTBV revealed the importance of nucleotide composition of the landing sequence for efficient shunting, indicating that the mechanism of ribosome shunting is evolutionary conserved in plant pararetroviruses.


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