The metaphorical swiss army knife: The multitude and diverse roles of HEAT domains in eukaryotic translation initiation

Stöppler, Daniel; Marintchev, Assen; Arthanari, Haribabu

doi:10.1093/nar/gkac342

Cited by 12 publications

(9 citation statements)

References 210 publications

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“…Both homologues have three HEAT domains: MIF4G, MA3, and W2 (Figure 2A). The X-ray diffraction data have been obtained for all three HEAT domains and the eIF4E-binding site of eIF4G1 (Friedrich et al 2022), and for MIF4G (residues 61-323) (Virgili et al 2013), MA3, and W2 domains (540-897) of eIF4G2 (Figure 2A) (Fan et al 2010;Liberman et al 2008). Maximum structural similarity is observed between the MIF4G domains of eIF4G1 and eIF4G2 (39% sequence identity, 59% similarity; see Figure 2B) (Virgili et al 2013), which are both responsible for the interaction with eIF4A.…”

Section: Structure Of the Eif4g2 Proteinmentioning

confidence: 99%

“…There is a recent detailed review of eIF4G1 and eIF4G2 structures ( Friedrich et al 2022 ), therefore we will just briefly outline some important points. Structural analysis of full-length eIF4G1 (the longest isoform consists of 1599 amino acids in humans) and eIF4G2 (907 amino acids in humans) has not yet been performed.…”

Section: Structure Of Eif4g2 and Its Expressionmentioning

confidence: 99%

“…2 A). The X-ray diffraction data have been obtained for all three HEAT domains and the eIF4E-binding site of eIF4G1 ( Friedrich et al 2022 ), and for MIF4G (residues 61–323) ( Virgili et al 2013 ), MA3, and W2 domains (540–897) of eIF4G2 ( Fig. 2 A; Liberman et al 2008 ; Fan et al 2010 ).…”

Section: Structure Of Eif4g2 and Its Expressionmentioning

confidence: 99%

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Specific mechanisms of translation initiation in higher eukaryotes: the eIF4G2 story

Shestakova

Smirnova

Shatsky

et al. 2022

RNA

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The eukaryotic initiation factor 4G2 (eIF4G2, DAP5, Nat1, p97) was discovered in 1997. Over the past two decades, dozens of papers have presented contradictory data on eIF4G2 function. Since its identification, eIF4G2 has been assumed to participate in noncanonical translation initiation mechanisms, but recent results indicate that it can be involved in scanning as well. In particular, eIF4G2 provides leaky scanning through some upstream open reading frames (uORFs), which are typical for long 5’ UTRs of mRNAs from higher eukaryotes. It is likely the protein can also help the ribosome overcome other impediments during scanning of the 5’ UTRs of animal mRNAs. This may explain the need for eIF4G2 in higher eukaryotes, as many mRNAs that encode regulatory proteins have rather long and highly structured 5’ UTRs. Additionally, they often bind to various proteins, which also hamper the movement of scanning ribosomes. This review discusses the suggested mechanisms of eIF4G2 action, denotes obscure or inconsistent results, and proposes ways to uncover other fundamental mechanisms in which this important protein factor may be involved in higher eukaryotes.

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Section: Structure Of the Eif4g2 Proteinmentioning

confidence: 99%

Section: Structure Of Eif4g2 and Its Expressionmentioning

confidence: 99%

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Specific mechanisms of translation initiation in higher eukaryotes: the eIF4G2 story

Shestakova

Smirnova

Shatsky

et al. 2022

RNA

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“…Given the elastic characteristics of solenoid domains 22,23,[27][28][29][30][31][32][33][34][35][36] and examples of helical repeat proteins, like the catenin core complex in adherens junctions 37,38 and talin in focal adhesions 39,40 , it seems plausible that GAC may act as a spring-like connection between the short (~100 nm) actin filaments [41][42][43] and the adhesion complex that is formed during gliding motility and invasion (Fig. 7).…”

Section: Elastic Spring Model For Gac In Gliding Motilitymentioning

confidence: 99%

Structure ofToxoplasma gondiiglideosome-associated connector suggests a role as an elastic element in actomyosin force generation for gliding motility

Hung

Chen

Pires

et al. 2022

Preprint

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Toxoplasma gondii glideosome-associated connector (GAC) is a giant armadillo-repeat protein, essential for parasite motility and conserved across Apicomplexa. It connects actin filaments to the plasma membrane via interactions with phosphatidic acid and membrane-spanning adhesins. It is unclear how GAC contributes to gliding motility and invasion and why such a large connector is needed. We determined the crystal structure of full-length T. gondii GAC at 2.3 Å resolution and explored its conformational space in solution using small-angle X-ray scattering and cryogenic electron microscopy. The crystal structure reveals a compact conformation but, in solution, GAC adopts both compact and extended forms. The PH domain stabilizes the compact form and may act as a switch triggered by membrane sensing. Based on its spring-like architecture, we suggest a role for GAC as an elastic element in actomyosin force generation during gliding motility and invasion.

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“…The N-terminal domain of GCN1 is necessary for robust ribosome binding [39][40][41]. Downstream of this N-terminal domain is a region containing several HEAT repeats, repetitive arrays of short amphiphilic α-helices, that are involved in the formation of protein-protein interactions (see Figure 2A) [42,43]. The C-terminal domain of GCN1 also interacts with colliding ribosomes and mediates the interaction between GCN1 and GCN2 [41,44].…”

Section: Introductionmentioning

confidence: 99%

RNAi-Mediated Knockdown of Acidic Ribosomal Stalk Protein P1 Arrests Egg Development in Adult Female Yellow Fever Mosquitoes, Aedes aegypti

Lamsal,

Luker,

Pinch

et al. 2024

Insects

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After taking a blood meal, the fat body of the adult female yellow fever mosquito, Aedes aegypti, switches from a previtellogenic state of arrest to an active state of synthesizing large quantities of yolk protein precursors (YPPs) that are crucial for egg development. The synthesis of YPPs is regulated at both the transcriptional and translational levels. Previously, we identified the cytoplasmic protein general control nonderepressible 1 (GCN1) as a part of the translational regulatory pathway for YPP synthesis. In the current study, we used the C-terminal end of GCN1 to screen for protein–protein interactions and identified 60S acidic ribosomal protein P1 (P1). An expression analysis and RNAi-mediated knockdown of P1 was performed to further investigate the role of P1 in mosquito reproduction. We showed that in unfed (absence of a blood meal) adult A. aegypti mosquitoes, P1 was expressed ubiquitously in the mosquito organs and tissues tested. We also showed that the RNAi-mediated knockdown of P1 in unfed adult female mosquitoes resulted in a strong, transient knockdown with observable phenotypic changes in ovary length and egg deposition. Our results suggest that 60S acidic ribosomal protein P1 is necessary for mosquito reproduction and is a promising target for mosquito population control.

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The metaphorical swiss army knife: The multitude and diverse roles of HEAT domains in eukaryotic translation initiation

Cited by 12 publications

References 210 publications

Specific mechanisms of translation initiation in higher eukaryotes: the eIF4G2 story

Specific mechanisms of translation initiation in higher eukaryotes: the eIF4G2 story

Structure ofToxoplasma gondiiglideosome-associated connector suggests a role as an elastic element in actomyosin force generation for gliding motility

RNAi-Mediated Knockdown of Acidic Ribosomal Stalk Protein P1 Arrests Egg Development in Adult Female Yellow Fever Mosquitoes, Aedes aegypti

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