Two Arabidopsis Loci Encode Novel Eukaryotic Initiation Factor 4E Isoforms That Are Functionally Distinct from the Conserved Plant Eukaryotic Initiation Factor 4E

Patrick, Ryan M.; Mayberry, Laura K.; Choy, Grace; Woodard, Lauren E.; Liu, Joceline S.; White, Allyson; Mullen, Rebecca; Tanavin, Toug M.; Latz, Christopher A.; Browning, Karen S.

doi:10.1104/pp.113.227785

Cited by 35 publications

(48 citation statements)

References 58 publications

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“…A number of forms of eIF4E have evolved in other organisms with special functions such as recognition of tri-methylated caps or tissuespecific regulation; however, some of these proteins have lost either their ability to bind m 7 G or eIF4G poising them as potential inhibitors or repressors of initiation (Joshi et al, 2005;Rhoads, 2009). eIF4E1b and eIF4E1c from Arabidopsis were found to bind eIF4G and to m 7 G-affinity resin and thus function biochemically in vitro as canonical cap-binding proteins (Patrick et al, 2014;Kropiwnicka et al, 2015). However, the double mutant eIF4E eIFiso4E is lethal suggesting that eIF4E1b and eIF4E1c are not able to replace eIF4E in vivo (Callot and Gallois, 2014;Patrick et al, 2014).…”

Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

“…eIF4E1b and eIF4E1c from Arabidopsis were found to bind eIF4G and to m 7 G-affinity resin and thus function biochemically in vitro as canonical cap-binding proteins (Patrick et al, 2014;Kropiwnicka et al, 2015). However, the double mutant eIF4E eIFiso4E is lethal suggesting that eIF4E1b and eIF4E1c are not able to replace eIF4E in vivo (Callot and Gallois, 2014;Patrick et al, 2014).…”

Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

“…Arabidopsis thaliana has three genes for the class 1 eIF4E (eIF4E, eIF4E1b, eIF4E1c) and one gene for eIFiso4E (Patrick and Browning, 2012;Patrick et al, 2014). eIF4E is the most highly expressed; the other two eIF4E genes (eIF4E1b, eIF4E1c) correspond to a tandem duplication event within the Brassicaceae with evidence that only eIF4E1b generates a transcript (Patrick and Browning, 2012) (see Table 1 for accession numbers).…”

Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

“…All higher plants have three forms of the cap-binding proteins, eIF4E, eIFiso4E (plant-specific) and 4EHP (4E homologous protein) which all bind to m 7 GTP-Sepharose (Ruud et al, 1998;Patrick et al, 2014;Kropiwnicka et al, 2015). eIF4E and eIFiso4E are both class 1 cap-binding proteins (Joshi et al, 2005) and form the eIF4F and eIFiso4F complexes with their respective subunits, eIF4G and eIFiso4G (Mayberry et al, 2011;Patrick and Browning, 2012).…”

Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

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Mechanism of Cytoplasmic mRNA Translation

Browning

Bailey‐Serres

2015

The Arabidopsis Book

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174

198

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Protein synthesis is a fundamental process in gene expression that depends upon the abundance and accessibility of the mRNA transcript as well as the activity of many protein and RNA-protein complexes. Here we focus on the intricate mechanics of mRNA translation in the cytoplasm of higher plants. This chapter includes an inventory of the plant translational apparatus and a detailed review of the translational processes of initiation, elongation, and termination. The majority of mechanistic studies of cytoplasmic translation have been carried out in yeast and mammalian systems. The factors and mechanisms of translation are for the most part conserved across eukaryotes; however, some distinctions are known to exist in plants. A comprehensive understanding of the complex translational apparatus and its regulation in plants is warranted, as the modulation of protein production is critical to development, environmental plasticity and biomass yield in diverse ecosystems and agricultural settings.

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Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

Section: The Cast Of Cap-binding Proteins: Eif4e Eifiso4e and 4ehpmentioning

confidence: 99%

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Mechanism of Cytoplasmic mRNA Translation

Browning

Bailey‐Serres

2015

The Arabidopsis Book

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174

198

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“…As the eif4e triple null mutant is not viable (26), it could not be included. Progeny homozygous for the Luc transgene and null for the initiation factor were isolated.…”

Section: Each Eif4g Isoformmentioning

confidence: 99%

Eukaryotic Initiation Factor eIFiso4G1 and eIFiso4G2 Are Isoforms Exhibiting Distinct Functional Differences in Supporting Translation in Arabidopsis

Gallie

2016

Journal of Biological Chemistry

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The eukaryotic translation initiation factor (eIF) 4G is required during protein synthesis to promote the assembly of several factors involved in the recruitment of a 40S ribosomal subunit to an mRNA. Although many eukaryotes express two eIF4G isoforms that are highly similar, the eIF4G isoforms in plants, referred to as eIF4G and eIFiso4G, are highly divergent in size, sequence, and domain organization but both can interact with eIF4A, eIF4B, eIF4E isoforms, and the poly(A)-binding protein.Nevertheless, eIF4G and eIFiso4G from wheat exhibit preferences in the mRNAs they translate optimally. For example, mRNA containing the 5-leader (called ⍀) of tobacco mosaic virus preferentially uses eIF4G in wheat germ lysate. In this study, the eIF4G isoform specificity of ⍀ was used to examine functional differences of the eIF4G isoforms in Arabidopsis. As in wheat, ⍀-mediated translation was reduced in an eif4g null mutant. Loss of the eIFiso4G1 isoform, which is similar in sequence to wheat eIFiso4G, did not substantially affect ⍀-mediated translation. However, loss of the eIFiso4G2 isoform substantially reduced ⍀-mediated translation. eIFiso4G2 is substantially divergent from eIFiso4G1 and is present only in the Brassicaceae, suggesting a recent evolution. eIFiso4G2 isoforms exhibit sequence-specific differences in regions representing partner protein and RNA binding sites. Loss of any eIF4G isoform also resulted in a substantial reduction in reporter transcript level. These results suggest that eIFiso4G2 appeared late in plant evolution and exhibits more functional similarity with eIF4G than with eIFiso4G1 during ⍀-mediated translation.The synthesis of proteins from cellular mRNAs requires several translation initiation factors that assist in recruiting the 40S ribosomal subunit to an mRNA as well as in the recognition of the initiation codon and in the assembly of the 80S ribosome (1-3). Eukaryotic initiation factor (eIF) 4F is essential to promote 40S subunit binding to an mRNA and to assist in 40S subunit scanning of the 5Ј-leader in search of the initiation codon. eIF4F is a multisubunit factor composed of eIF4E, which binds the 5Ј-cap structure; the RNA helicase, eIF4A, which unwinds the secondary structure in a 5Ј-leader that would otherwise inhibit 40S subunit scanning; and the scaffolding protein, eIF4G, which interacts with eIF4E, eIF4A, eIF4B (which stimulates the RNA helicase activity of eIF4A), eIF3 (required for 40 S binding to an mRNA), and the poly(A)-binding protein (PABP) 2 (2, 4 -6). The interactions between eIF4G and eIF4E and between eIF4G and PABP results in mRNA circularization that stimulates translation by promoting 40S subunit recruitment (7,8). An interaction between eIF4B and PABP further increases the affinity for poly(A) RNA of PABP (9 -11). These factors, therefore, are necessary for the efficient translation of most mRNAs.Although plants express two forms of eIF4G as do many eukaryotes (12), the plant isoforms are more divergent from each other than observed between eIF4G isoforms in othe...

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Tools and targets: The dual role of plant viruses in CRISPR–Cas genome editing

Uranga

Daròs

2022

The Plant Genome

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The recent emergence of tools based on the clustered, regularly interspaced, short palindromic repeats (CRISPR) and CRISPR‐associated (Cas) proteins have revolutionized targeted genome editing, thus holding great promise to both basic plant science and precision crop breeding. Conventional approaches for the delivery of editing components rely on transformation technologies or transient delivery to protoplasts, both of which are time‐consuming, laborious, and can raise legal concerns. Alternatively, plant RNA viruses can be used as transient delivery vectors of CRISPR–Cas reaction components, following the so‐called virus‐induced genome editing (VIGE). During the last years, researchers have been able to engineer viral vectors for the delivery of CRISPR guide RNAs and Cas nucleases. Considering that each viral vector is limited to its molecular biology properties and a specific host range, here we review recent advances for improving the VIGE toolbox with a special focus on strategies to achieve tissue‐culture‐free editing in plants. We also explore the utility of CRISPR–Cas technology to enhance biotic resistance with a special focus on plant virus diseases. This can be achieved by either targeting the viral genome or modifying essential host susceptibility genes that mediate in the infection process. Finally, we discuss the challenges and potential that VIGE holds in future breeding technologies.

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Two Arabidopsis Loci Encode Novel Eukaryotic Initiation Factor 4E Isoforms That Are Functionally Distinct from the Conserved Plant Eukaryotic Initiation Factor 4E

Cited by 35 publications

References 58 publications

Mechanism of Cytoplasmic mRNA Translation

Mechanism of Cytoplasmic mRNA Translation

Eukaryotic Initiation Factor eIFiso4G1 and eIFiso4G2 Are Isoforms Exhibiting Distinct Functional Differences in Supporting Translation in Arabidopsis

Tools and targets: The dual role of plant viruses in CRISPR–Cas genome editing

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