Fig. 6.
Fig. 6. Effect of upstream ORFs on TPO mRNA translation. (Top) Simplified drawing of TPO mRNA with only one uORF in the 5′-UTR followed by the TPO coding region (open boxes). According to the ribosomal scanning model, the 40 S ribosomal subunit will bind the cap structure at the 5′ end of the mRNA and scan the mRNA until it encounters the first AUG, where a functional ribosome is assembled. The ribosome will initiate translation and synthesize a short peptide until a stop codon is reached. Here the ribosome dissociates from the mRNA. This will prevent the ribosome from reaching the physiological TPO start codon. However, a minor proportion of 40 S subunits may remain associated with the mRNA and continue scanning for a downstream AUG. (Bottom) TPO 5′-UTR with point mutations in all uAUG codons will allow the 40 S subunit to reach the physiological start site more efficiently and initiate translation of the TPO protein.

Effect of upstream ORFs on TPO mRNA translation. (Top) Simplified drawing of TPO mRNA with only one uORF in the 5′-UTR followed by the TPO coding region (open boxes). According to the ribosomal scanning model, the 40 S ribosomal subunit will bind the cap structure at the 5′ end of the mRNA and scan the mRNA until it encounters the first AUG, where a functional ribosome is assembled. The ribosome will initiate translation and synthesize a short peptide until a stop codon is reached. Here the ribosome dissociates from the mRNA. This will prevent the ribosome from reaching the physiological TPO start codon. However, a minor proportion of 40 S subunits may remain associated with the mRNA and continue scanning for a downstream AUG. (Bottom) TPO 5′-UTR with point mutations in all uAUG codons will allow the 40 S subunit to reach the physiological start site more efficiently and initiate translation of the TPO protein.

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