Study of translational control of eukaryotic gene expression using yeast.

Eukaryotic cells respond to starvation by decreasing the rate of general protein synthesis while inducing translation of specific mRNAs encoding transcription factors GCN4 (yeast) or ATF4 (humans). Both responses are elicited by phosphorylation of translation initiation factor 2 (eIF2) and the attendant inhibition of its nucleotide exchange factor eIF2B-decreasing the binding to 40S ribosomes of methionyl initiator tRNA in the ternary complex (TC) with eIF2 and GTP. The reduction in TC levels enables scanning ribosomes to bypass the start codons of upstream open reading frames in the GCN4 mRNA leader and initiate translation at the authentic GCN4 start codon. We exploited the fact that GCN4 translation is a sensitive reporter of defects in TC recruitment to identify the catalytic and regulatory subunits of eIF2B. More recently, we implicated the C-terminal domain of eIF1A in 40S-binding of TC in vivo. Interestingly, we found that TC resides in a multifactor complex (MFC) with eIF3, eIF1, and the GTPase-activating protein for eIF2, known as eIF5. Our biochemical and genetic analyses indicate that physical interactions between MFC components enhance TC binding to 40S subunits and are required for wild-type translational control of GCN4. MFC integrity and eIF3 function also contribute to post-assembly steps in the initiation pathway that impact GCN4 expression. Thus, apart from its critical role in the starvation response, GCN4 regulation is a valuable tool for dissecting the contributions of multiple translation factors in the eukaryotic initiation pathway.

Domains of eIF1A that mediate binding to eIF2, eIF3 and eIF5B and promote ternary complex recruitment in vivo.

Translation initiation factor 1A (eIF1A) is predicted to bind in the decoding site of the 40S ribosome and has been implicated in recruitment of the eIF2-GTP-Met-tRNA i Met ternary complex (TC) and ribosomal scanning. We show that the unstructured C-terminus of eIF1A interacts with the C-terminus of eIF5B, a factor that stimulates 40S-60S subunit joining, and removal of this domain of eIF1A diminishes translation initiation in vivo. These findings support the idea that eIF1A-eIF5B association is instrumental in releasing eIF1A from the ribosome after subunit joining. A larger C-terminal truncation that removes a 3(10) helix in eIF1A deregulates GCN4 translation in a manner suppressed by overexpressing TC, implicating eIF1A in TC binding to 40S ribosomes in vivo. The unstructured N-terminus of eIF1A interacts with eIF2 and eIF3 and is required at low temperatures for a step following TC recruitment. We propose a modular organization for eIF1A wherein a core ribosome-binding domain is flanked by flexible segments that mediate interactions with other factors involved in recruitment of TC and release of eIF1A at subunit joining.

The GCN2 eIF2alpha kinase is required for adaptation to amino acid deprivation in mice.

The GCN2 eIF2alpha kinase is essential for activation of the general amino acid control pathway in yeast when one or more amino acids become limiting for growth. GCN2's function in mammals is unknown, but must differ, since mammals, unlike yeast, can synthesize only half of the standard 20 amino acids. To investigate the function of mammalian GCN2, we have generated a Gcn2(-/-) knockout strain of mice. Gcn2(-/-) mice are viable, fertile, and exhibit no phenotypic abnormalities under standard growth conditions. However, prenatal and neonatal mortalities are significantly increased in Gcn2(-/-) mice whose mothers were reared on leucine-, tryptophan-, or glycine-deficient diets during gestation. Leucine deprivation produced the most pronounced effect, with a 63% reduction in the expected number of viable neonatal mice. Cultured embryonic stem cells derived from Gcn2(-/-) mice failed to show the normal induction of eIF2alpha phosphorylation in cells deprived of leucine. To assess the biochemical effects of the loss of GCN2 in the whole animal, liver perfusion experiments were conducted. Histidine limitation in the presence of histidinol induced a twofold increase in the phosphorylation of eIF2alpha and a concomitant reduction in eIF2B activity in perfused livers from wild-type mice, but no changes in livers from Gcn2(-/-) mice.

Development and characterization of a reconstituted yeast translation initiation system.

To provide a bridge between in vivo and in vitro studies of eukaryotic translation initiation, we have developed a reconstituted translation initiation system using components from the yeast Saccharomyces cerevisiae. We have purified a minimal set of initiation factors (elFs) that, together with yeast 80S ribosomes, GTP, and initiator methionyl-tRNA, are sufficient to assemble active initiation complexes on a minimal mRNA template. The kinetics of various steps in the pathway of initiation complex assembly and the formation of the first peptide bond in vitro have been explored. The formation of active initiation complexes in this system is dependent on ribosomes, mRNA, Met-tRNAi, GTP hydrolysis, elF1, elF1A, elF2, elF5, and elF5B. Our data indicate that elF1 and elF1A both facilitate the binding of the elF2 x GTP x Met-tRNAi complex to the 40S ribosomal subunit to form the 43S complex. elF5 stimulates a step after 43S complex formation, consistent with its proposed role in activating GTP hydrolysis by elF2 upon initiation codon recognition. The presence of elF5B is required for the joining of the 40S and 60S subunits to form the 80S initiation complex. The step at which each of these factors acts in this reconstituted system is in agreement with previous data from in vivo studies and work using reconstituted mammalian systems, indicating that the system recapitulates fundamental events in translation initiation in eukaryotic cells. This system should allow us to couple powerful yeast genetic and molecular biological experiments with in vitro kinetic and biophysical experiments, yielding a better understanding of the molecular mechanics of this central, complex process.