mRNA degradation predominantly proceeds through two alternative routes: the 533 pathway, which requires deadenylation followed by decapping and 533 hydrolysis; and the 335 pathway, which involves deadenylation followed by 335 hydrolysis and finally decapping. The mechanisms and relative contributions of each pathway are not fully understood. We investigated the effects of different cap structure (Gp 3 G, m 7 Gp 3 G, or m 2 7,3-O Gp 3 G) and 3 termini (A 31 , A 60 , or G 16 ) on both translation and mRNA degradation in mammalian cells. The results indicated that cap structures that bind eIF4E with higher affinity stabilize mRNA to degradation in vivo. mRNA stability depends on the ability of the 5 terminus to bind eIF4E, not merely the presence of a blocking group at the 5-end. Introducing a stem-loop in the 5-UTR that dramatically reduces translation, but keeping the cap structure the same, does not alter the rate of mRNA degradation. The 5Ј terminus of all eukaryotic cellular mRNAs is modified with a 5Ј-5Ј m 7 GTP-containing cap (1). Caps fulfill a variety of functions in the synthesis, translation, and degradation of mRNA. The presence of the 5Ј cap structure increases both the accuracy and efficiency of pre-mRNA splicing (2, 3). The cap on pre-mRNA interacts with the nuclear cap-binding complex, which remains bound and plays an active role during RNA processing and export (4). In the cytosol, the cap structure is required for efficient translation of mRNA. The cap is specifically recognized by the translational initiation factor eIF4E (5, 6). Binding of eIF4E to the cap occurs during formation of the 48 S initiation complex, which is rate limiting for translation initiation under normal conditions (7,8). Finally, the cap serves as one determinant of mRNA degradation. Capped mRNAs are more stable than their uncapped counterparts (9). The cap structure helps to protect RNA from degradation by 5Ј33Ј-exonucleases located in the cytosol and nucleus, as demonstrated in both Saccharomyces cerevisiae (10) and mammalian cells (11,12).A second stability element in mRNA is the 3Ј-terminal poly(A) tract. PABP 2,3 binds to poly(A) and is essential for the stability provided by this element, protecting mRNA against exonucleolytic degradation (12-15). PABP also binds to the N terminus of eIF4G (16) and stabilizes the eIF4G⅐eIF4E complex, enhancing translational reinitiation (17, 18). The stimulation conferred by the cap and poly(A) tract are synergistic rather than additive (19,20). Thus, for both translation and degradation of mRNA, elements binding to the 5Ј and 3Ј termini act cooperatively and in close proximity.There are two major pathways by which polyadenylated mRNA is degraded in eukaryotic cells, a 5Ј33Ј pathway and a 3Ј35Ј pathway, as well as two specialized routes for aberrant mRNA degradation (21). In both the 5Ј33Ј and 3Ј35Јpathways, shortening of the poly(A) tract initiates mRNA decay. There are several mechanism of deadenylation (21), but one of them involves a poly(A)-specific ribonuclease (22), an enzyme tha...
