Human eIF4E promotes mRNA restructuring by stimulating eIF4A helicase activity

Elevated eukaryotic initiation factor 4E (eIF4E) levels frequently occur in a variety of human cancers. Overexpression of eIF4E promotes cellular transformation by selectively increasing the translation of proliferative and prosurvival mRNAs. These mRNAs possess highly structured 5'-UTRs that impede ribosome recruitment and scanning, yet the mechanism for how eIF4E abundance elevates their translation is not easily explained by its cap-binding activity. Here, we show that eIF4E possesses an unexpected second function in translation initiation by strongly stimulating eukaryotic initiation factor 4A (eIF4A) helicase activity. Importantly, we demonstrate that this activity promotes mRNA restructuring in a manner that is independent of its cap-binding function. To explain these findings, we show that the eIF4E-binding site in eukaryotic initiation factor 4G (eIF4G) functions as an autoinhibitory domain to modulate its ability to stimulate eIF4A helicase activity. Binding of eIF4E counteracts this autoinhibition, enabling eIF4G to stimulate eIF4A helicase activity. Finally, we have successfully separated the two functions of eIF4E to show that its helicase promoting activity increases the rate of translation by a mechanism that is distinct from its cap-binding function. Based on our results, we propose that maintaining a connection between eIF4E and eIF4G throughout scanning provides a plausible mechanism to explain how eIF4E abundance selectively stimulates the translation of highly structured proliferation and tumor-promoting mRNAs

Factor-dependent processivity in human eIF4A DEAD-box helicase

During eukaryotic translation initiation, the small ribosomal subunit, assisted by initiation factors, locates the messenger RNA start codon by scanning from the 5' cap. This process is powered by the eukaryotic initiation factor 4A (eIF4A), a DEAD-box helicase. eIF4A has been thought to unwind structures formed in the untranslated 5' region via a nonprocessive mechanism. Using a single-molecule assay, we found that eIF4A functions instead as an adenosine triphosphate-dependent processive helicase when complexed with two accessory proteins, eIF4G and eIF4B. Translocation occurred in discrete steps of 11 ± 2 base pairs, irrespective of the accessory factor combination. Our findings support a memory-less stepwise mechanism for translation initiation and suggest that similar factor-dependent processivity may be shared by other members of the DEAD-box helicase family

Real-time fluorescence assays to monitor duplex unwinding and ATPase activities of helicases.

Many physiological functions of helicases are dependent on their ability to unwind nucleic acid duplexes in an ATP-dependent fashion. Determining the kinetic frameworks of these processes is crucial to understanding how these proteins function. We recently developed a fluorescence assay to monitor RNA duplex unwinding by DEAD-box helicases in real time. In this assay, two fluorescently modified short reporter oligonucleotides are annealed to an unmodified RNA loading strand of any length so that the fluorescent moieties of the two reporters find themselves in close proximity to each other and fluorescence is quenched. One reporter is modified with cyanine 3 (Cy3), whereas the other is modified with a spectrally paired black-hole quencher (BHQ). As the helicase unwinds the loading strand, the enzyme displaces the Cy3-modified reporter, which will bind to a capture or competitor DNA strand, permanently separating it from the BHQ-modified reporter. Complete separation of the Cy3-modified reporter strand is thus detected as an increase in total fluorescence. This assay is compatible with reagentless biosensors to monitor ATPase activity so that the coupling between ATP hydrolysis and duplex unwinding can be determined. With the protocol described, obtaining data and analyzing results of unwinding and ATPase assays takes ∼4 h

Structural Analysis of the DAP5 MIF4G Domain and Its Interaction with eIF4A

SummaryDeath-associated protein 5 (DAP5/p97) is a homolog of the eukaryotic initiation factor 4G (eIF4G) that promotes the IRES-driven translation of multiple cellular mRNAs. Central to its function is the middle domain (MIF4G), which recruits the RNA helicase eIF4A. The middle domain of eIF4G consists of tandem HEAT repeats that coalesce to form a solenoid-type structure. Here, we report the crystal structure of the DAP5 MIF4G domain. Its overall fold is very similar to that of eIF4G; however, significant conformational variations impart distinct surface properties that could explain the observed differences in IRES binding between the two proteins. Interestingly, quantitative analysis of the DAP5-eIF4A interaction using isothermal titration calorimetry reveals a 10-fold lower affinity than with the eIF4G-eIF4A interaction that appears to affect their ability to stimulate eIF4A RNA unwinding activity in vitro. This difference in stability of the complex may have functional implications in selecting the mode of translation initiation

Real-time fluorescence assays to monitor duplex unwinding and ATPase activities of helicases.

Many physiological functions of helicases are dependent on their ability to unwind nucleic acid duplexes in an ATP-dependent fashion. Determining the kinetic frameworks of these processes is crucial to understanding how these proteins function. We recently developed a fluorescence assay to monitor RNA duplex unwinding by DEAD-box helicases in real time. In this assay, two fluorescently modified short reporter oligonucleotides are annealed to an unmodified RNA loading strand of any length so that the fluorescent moieties of the two reporters find themselves in close proximity to each other and fluorescence is quenched. One reporter is modified with cyanine 3 (Cy3), whereas the other is modified with a spectrally paired black-hole quencher (BHQ). As the helicase unwinds the loading strand, the enzyme displaces the Cy3-modified reporter, which will bind to a capture or competitor DNA strand, permanently separating it from the BHQ-modified reporter. Complete separation of the Cy3-modified reporter strand is thus detected as an increase in total fluorescence. This assay is compatible with reagentless biosensors to monitor ATPase activity so that the coupling between ATP hydrolysis and duplex unwinding can be determined. With the protocol described, obtaining data and analyzing results of unwinding and ATPase assays takes ∼4 h