Roles and interactions of the specialized initiation factors EIF4E2, EIF4E5, and EIF4E6 in Trypanosoma brucei: EIF4E2 maintains the abundances of S-phase mRNAs

Trypanosoma brucei has six versions of the cap-binding translation initiation factor EIF4E. We investigated the functions of EIF4E2, EIF4E3, EIF4E5, and EIF4E6 in bloodstream forms. We confirmed the protein associations previously found in procyclic forms and detected specific copurification of some RNA-binding proteins. Bloodstream forms lacking EIF4E5 grew normally and differentiated to replication-incompetent procyclic forms. Depletion of EIF4E6 inhibited bloodstream-form trypanosome growth and translation. EIF4E2 copurified only the putative RNA-binding protein SLBP2. Bloodstream forms lacking EIF4E2 multiplied slowly, had a low maximal cell density, and expressed the stumpy-form marker PAD1 but showed no evidence for enhanced stumpy-form signaling. EIF4E2 knock-out cells differentiated readily to replication-competent procyclic forms. EIF4E2 was strongly associated with a subset of mRNAs that are maximally abundant in the S-phase, and these all had decreased abundances in EIF4E2 knock-out cells. Three EIF4E2 target mRNAs are also bound and stabilized by the Pumilio domain protein PUF9. Yeast 2-hybrid results suggested that PUF9 interacts directly with SLBP2, but PUF9 was not detected in EIF4E2 pull-downs. We speculate that the EIF4E2-SLBP2 complex might interact with its target mRNAs, perhaps via PUF9, only early during G1/S, stabilizing the mRNAs in preparation for translation later in S-phase or in early G2.

Automated summary

In this study, the functions of different versions of the cap-binding translation initiation factor EIF4E in Trypanosoma brucei were investigated. It was found that EIF4E2 is associated with the RNA-binding protein SLBP2 in bloodstream forms, while EIF4E5 has no impact on growth and differentiation. Additionally, EIF4E2 is strongly associated with a subset of mRNAs that are maximally abundant in the S-phase, with their abundances decreased in EIF4E2 knock-out cells.