Inhibition of mRNA Turnover in Yeast by an xrn1 Mutation Enhances the Requirement for eIF4E Binding to eIF4G and for Proper Capping of Transcripts by Ceg1p

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Inhibition of mRNA Turnover in Yeast by an xrn1 Mutation Enhances the Requirement for eIF4E Binding to eIF4G and for Proper Capping of Transcripts by Ceg1p

Justin T. Brown^a, Xianmei Yang^a, and Arlen W. Johnson^a
^a Section of Molecular Genetics and Microbiology and the Institute for Cellular and Molecular Biology, University of Texas, Austin, Texas 78712-1095

Corresponding author: Arlen W. Johnson, Molecular Genetics and Microbiology, Experimental Science Bldg. 325, University of Texas, Austin, TX 78712-1095., arlen{at}mail.utexas.edu (E-mail)

Communicating editor: A. G. HINNEBUSCH

Null mutants of XRN1, encoding the major cytoplasmic exoribonucleasein yeast, are viable but accumulate decapped, deadenylated transcripts.A screen for mutations synthetic lethal with xrn1 ${Delta}$ identifieda mutation in CDC33, encoding eIF4E. This mutation (glutamateto glycine at position 72) affected a highly conserved residueinvolved in interaction with eIF4G. Synthetic lethality betweenxrn1 and cdc33 was not relieved by high-copy expression of eIF4Gor by disruption of the yeast eIF4E binding protein Caf20p.High-copy expression of a mutant eIF4G defective for eIF4E bindingresulted in a dominant negative phenotype in an xrn1 mutant,indicating the importance of this interaction in an xrn1 mutant.Another allele of CDC33, cdc33-1, along with mutations in CEG1,encoding the nuclear guanylyltransferase, were also syntheticlethal with xrn1 ${Delta}$ , whereas mutations in PRT1, encoding a subunitof eIF3, were not. Mutations in CDC33, CEG1, PRT1, PAB1, andTIF4631, encoding eIF4G1, have been shown to lead to destabilizationof mRNAs. Although such destabilization in cdc33, ceg1, andpab1 mutants can be partially suppressed by an xrn1 mutation,we observed synthetic lethality between xrn1 and either cdc33or ceg1 and no suppression of the inviability of a pab1 nullmutation by xrn1 ${Delta}$ . Thus, the inhibition of mRNA turnover by blockingXrn1p function does not suppress the lethality of defects upstreamin the turnover pathway but it does enhance the requirementfor ⁷mG caps and for proper formation of the eIF4E/eIF4G caprecognition complex.

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