DEAD-box proteins (DBPs) are required in gene expression to facilitate changes to ribonucleoprotein complexes, but the cellular mechanisms and regulation of DBPs are not fully defined. Gle1 is a multifunctional regulator of DBPs with roles in mRNA export and translation. In translation, Gle1 modulates Ded1, a DBP required for initiation. However, overexpression causes defects, suggesting that Ded1 can promote or repress translation in different contexts. Here we show that expression suppresses the repressive effects of , and Gle1 counteracts Ded1 in translation assays Furthermore, Ded1 and Gle1 both affect assembly of pre-initiation complexes. Through mutation analysis and binding assays, we show that Gle1 inhibits Ded1 by reducing its affinity for RNA. Our results are consistent with a model wherein active Ded1 promotes translation, but inactive or excess Ded1 leads to translation repression. Gle1 can inhibit either role of Ded1, positioning it as a gatekeeper to optimize Ded1 activity to the appropriate level for translation. This study suggests a paradigm for finely controlling the activity of DEAD-box proteins to optimize their function in RNA-based processes. It also positions the versatile regulator Gle1 as a potential node for the coordination of different steps of gene expression.
Ded1 is a DEAD-box RNA helicase with essential roles in translation initiation. It binds to the eukaryotic initiation factor 4F (eIF4F) complex and promotes 48S preinitiation complex assembly and start-site scanning of 5′ untranslated regions of mRNAs. Most prior studies of Ded1 cellular function were conducted in steady-state conditions during nutrient-rich growth. In this work, however, we examine its role in the translational response during target of rapamycin (TOR)C1 inhibition and identify a novel function of Ded1 as a translation repressor. We show that C-terminal mutants of DED1 are defective in down-regulating translation following TORC1 inhibition using rapamycin. Furthermore, following TORC1 inhibition, eIF4G1 normally dissociates from translation complexes and is degraded, and this process is attenuated in mutant cells. Mapping of the functional requirements for Ded1 in this translational response indicates that Ded1 enzymatic activity and interaction with eIF4G1 are required, while homo-oligomerization may be dispensable. Our results are consistent with a model wherein Ded1 stalls translation and specifically removes eIF4G1 from translation preinitiation complexes, thus removing eIF4G1 from the translating mRNA pool and leading to the codegradation of both proteins. Shared features among DED1 orthologues suggest that this role is conserved and may be implicated in pathologies such as oncogenesis.
Divalent metal ions are components of numerous icosahedral virus capsids. Flock House virus (FHV), a small RNA virus of the family Nodaviridae, was utilized as an accessible model system with which to address the effects of metal ions on capsid structure and on the biology of virus-host interactions. Mutations at the calcium-binding sites affected FHV capsid stability and drastically reduced virus infectivity, without altering the overall architecture of the capsid. The mutations also altered the conformation of gamma, a membranedisrupting, virus-encoded peptide usually sequestered inside the capsid, by increasing its exposure under neutral pH conditions. Our data demonstrate that calcium binding is essential for maintaining a pH-based control on gamma exposure and host membrane disruption, and they reveal a novel rationale for the metal ion requirement during virus entry and infectivity. In the light of the phenotypes displayed by a calcium site mutant of FHV, we suggest that this mutant corresponds to an early entry intermediate formed in the endosomal pathway.During cellular entry, the capsids of nonenveloped viruses undergo conformational changes triggered by various host factors. The transitions include the exposure of membrane-active, hydrophobic viral polypeptides and the destabilization and disassembly of the capsid, culminating in the delivery of the viral genome to the cytoplasm. A detailed, stepwise pathway of disassembly is unavailable for most viruses and requires molecular characterization of the intermediates formed during this process. Replication of disassembly intermediates in vitro necessitates careful treatment of native virions to simulate conditions likely to be encountered inside host cells. Receptor binding induces conformational changes in poliovirus, and the poliovirus entry intermediates, the 135S and 80S particles, can be generated in vitro by treating the native virion with the purified receptor, or by heating (6,10,19). Reovirus, which requires cathepsin-mediated proteolysis in the late endosomes in order to undergo entry-related changes, produces infectious subvirion particles (ISVP) and core particles as disassembly intermediates upon treatment with proteases in vitro (11,14).Apart from receptors and cellular proteases, other host determinants affecting viruses include low pH and Ca 2ϩ depletion in specialized cellular compartments. The removal of Ca 2ϩ from capsids could be particularly crucial for viruses that depend on metal ions for assembly and stability, such as rotavirus, mouse polyomavirus, and dragon grouper nervous necrosis virus (DGNNV) (1,39,43). A few studies have reported that mutations at the metal-binding sites decrease virus infectivity by impairing the early stages of virus-host interaction and genome release (23,24). When Ca 2ϩ is removed from the capsids of plant viruses such as cowpea chlorotic mottle virus (CCMV), tomato bushy stunt virus (TBSV), and turnip crinkle virus (TCV) by metal chelators (2, 33, 35), the virion swells by almost 10% and becomes suscept...
Ded1 is a conserved RNA helicase that promotes translation initiation in steady-state conditions. Ded1 has also been shown to regulate translation during cellular stress and affect the dynamics of stress granules (SGs), accumulations of RNA and protein linked to translation repression. To better understand its role in stress responses, we examined Ded1 function in two different models: DED1 overexpression and oxidative stress. DED1 overexpression inhibits growth and promotes the formation of SGs. A ded1 mutant lacking the low-complexity C-terminal region ( ded1-ΔCT ), which mediates Ded1 oligomerization and interaction with the translation factor eIF4G1, suppressed these phenotypes, consistent with other stresses. During oxidative stress, a ded1-ΔCT mutant was defective in growth and in SG formation compared to wild-type cells, although SGs were increased rather than decreased in these conditions. Unlike stress induced by direct TOR inhibition, the phenotypes in both models were only partially dependent on eIF4G1 interaction, suggesting an additional contribution from Ded1 oligomerization. Furthermore, examination of the growth defects and translational changes during oxidative stress suggested that Ded1 plays a role during recovery from stress. Integrating these disparate results, we propose that Ded1 controls multiple aspects of translation and RNP dynamics in both initial stress responses and during recovery.
Ded1 is a conserved RNA helicase that promotes translation initiation in steady-state conditions. Ded1 has also been shown to regulate translation during cellular stress and affect the dynamics of stress granules (SGs), accumulations of RNA and protein linked to translation repression. To better understand its role in stress responses, we examined Ded1 function in two different models: DED1 overexpression and oxidative stress. DED1 overexpression inhibits growth and promotes the formation of SGs. A ded1 mutant lacking the low-complexity C-terminal region (ded1-ΔCT), which mediates Ded1 oligomerization and interaction with the translation factor eIF4G, suppressed these phenotypes, consistent with other stresses. During oxidative stress, a ded1-ΔCT mutant was defective in growth and in SG formation compared to wild-type cells, although SGs were increased rather than decreased in these conditions. Unlike stress induced by direct TOR inhibition, the phenotypes in both models were only partially dependent on eIF4G interaction, suggesting an additional contribution from Ded1 oligomerization. Furthermore, examination of the growth defects and translational changes during oxidative stress suggested that Ded1 plays a role during recovery from stress. Integrating these disparate results, we propose that Ded1 controls multiple aspects of translation and RNP dynamics in both initial stress responses and during recovery.
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