Abstract

In the present study we investigate the impact of highly stable coding region secondary structures on mRNA translation efficiency. By introducing antisense segments into the 3'non-translated region of human alpha-globin mRNA we are able to synthesize a series of transcripts in which site-specific secondary structures are introduced without altering the primary structure of the 5' non-translated region, the coding region, or the encoded protein product. Coding region duplexes in close proximity to the AUG initiation codon are found to inhibit translation severely to a degree equal to that of a duplex that extends into the 5' non-translated region. In contrast, mRNAs containing duplexes positioned further 3' in the coding region translate at levels that are significantly higher although are still below those of native alpha-globin mRNA. The primary determinant of translation inhibition by coding region duplexes appears to be the proximity of the duplex to the AUG initiation codon and reflects a parallel inhibition of monosome formation. These data demonstrate that extensive coding region secondary structures suppress translation to a minimal or to a substantial degree depending on their distance from the initiation codon.