Abstract
The p53 protein is one of the major cell cycle regulators. The protein is expressed as at least twelve protein isoforms resulting from the use of alternative promoters, alternative splicing or downstream initiation codons. Importantly, there is growing evidence that translation initiation of p53 mRNA may be regulated by the structure and length of the naturally occurring variants of the 5′-terminal region of p53 mRNA transcripts. Here, several mRNA constructs were synthesized with variable length of the p53 5′-terminal regions and encoding luciferase reporter protein, and their translation was monitored continuously in situ in a rabbit reticulocyte lysate system. Moreover, four additional mRNA constructs were prepared. In two constructs, the structural context of AUG1 initiation codon was altered while in the other two constructs, characteristic hairpin motifs present in the p53 5′-terminal region were changed. Translation of the last two constructs was also performed in the presence of the cap analogue to test the function of the 5′-terminal region in cap-independent translation initiation. Superposition of several structural factors connected with the length of the 5′-terminal region, stable elements of the secondary structure, structural environment of the initiation codon and IRES elements greatly influenced the ribosomal scanning and translation efficiency.
Highlights
The translation process determines the protein composition in the cell, and the translatome changes occurring during cell development or induced by external stimuli
The mRNA constructs consisted of various 5′-terminal regions of p53 mRNA and an identical coding sequence of Renilla luciferase (Figs 1, 3, 4 and 5, in which the secondary structures of the 5′-terminal regions of the constructs are shown)
The 5′ untranslated regions of p53 mRNA were terminated with initiation codons AUG1 for p53 protein or AUG2 for Δ40p53 isoform
Summary
The translation process determines the protein composition in the cell, and the translatome changes occurring during cell development or induced by external stimuli. Once PIC binds to the cap structure it scans the 5′-terminal region in the 3′ direction and an ATP-dependent manner in order to find the initiation codon[5,6]. This ribosomal scanning mechanism is considered to be the predominant model of translation initiation in Eucaryota[1,7,8] in contrast to prokaryotic initiation involving direct rRNA – mRNA base-pairing interaction[9,10]. Recent data exclude the direct role of DHX29 protein in RNA unwinding It might rather bind the initiation complex, establishing contacts with different subunits of eIF3, thereby causing the rearrangement of the ribosomal complex. The clinical importance of those isoforms is not fully understood
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