Thus, the translational efficiencies of at least a subset of genes are affected similarly by the absence of eIF4G1 alone and the elimi nation of both eIF4G1 and eIF4G2 simultaneously. This is consistent with the conclusion that eIF4G1 and eIF4G2 perform essentially identical Inhibitors,Modulators,Libraries functions. A recent analysis of the consequences of depleting eIF4GI and eIF4GII with siRNAs in cultured mammalian cells reached certain conclusions congruent, and others that seem Inhibitors,Modulators,Libraries to differ, from our findings. It was found that depleting both eIF4GI and AV-951 eIF4GII reduced overall translation by only 20%, whereas depleting two eIF3 sub units provoked a stronger reduction, consistent with the greater requirement for eIF3 versus eIF4G we observed in yeast.
eIF4GI depletion reduced the trans lational efficiencies of a subset Inhibitors,Modulators,Libraries of mammalian mRNAs, including a group whose products function in mitochon drial regulation, bioenergetics, and cell proliferation. In accordance with our observations, there was no significant correlation between the presence of long or structured 5UTRs and the degree of eIF4GI dependence. This is con sistent with the aforementioned suggestion that eIF4GI is more important for 43S attachment than for subsequent scanning through the 5UTR. At odds with our results, however, the eIF4GI dependent class of mRNAs appeared to be somewhat enriched in those containing uORFs, and the presence of an uORF was shown to increase the eIF4GI dependence on translation. One possibility is that the majority of uORF containing mRNAs in yeast do not support appreciable reinitiation in WT cells, as this process has strict requirements for uORF length and cis acting sequences surrounding the stop codon.
In this event, eliminating the potential role of eIF4G Inhibitors,Modulators,Libraries in sti mulating reinitiation would be difficult to detect on a gen ome wide basis in yeast. Conclusions Our results indicate that eliminating both isoforms of eIF4G from yeast cells elicits a substantial reduction in the rate of translation initiation that is severe enough to block cell division, but does not evoke dramatic changes in the relative translational efficiencies of the majority of mRNAs. Rather, we observed a large scale narrowing of translational efficiencies, including mRNAs with higher or lower than average efficiencies, which is expected to disturb the stoichiometry of protein components com prising many cellular pathways and structures.