Eukaryotic translation initiation factor (eIF) 5A stimulates protein synthesis in Saccharomyces cerevisiae.

Within the field of eukaryotic protein synthesis, one factor remained putative for decades: eukaryotic translation initiation factor (eIF) 5A. Because eIF5A is an essential protein required for cell proliferation, and one easily targeted by inhibitors, identifying its role in the cell remains important and urgent. Recent reports support early findings that eIF5A stimulates protein synthesis and newly assign the factor a role in elongation rather than initiation. Here we show that eIF5A directly stimulates protein synthesis on native mRNAs, that rapid depletion of eIF5A in vivo immediately leads to a 2-fold inhibition of protein synthesis, and that both the immediate and lasting effects of eIF5A depletion are a reduction in polysome size concomitant with eIF5A depletion. Addition of purified eIF5A to a depleted lysate results in a roughly 2-fold stimulation of protein synthesis in vitro, a result consistent with both older methionyl-puromycin synthesis data and more recently published findings. We find that although eIF5A is not required for protein synthesis, it stimulates the process by about 2- to 3-fold. Our data, along with other published results, reinforce the conclusion that eIF5A stimulates protein synthesis with one important difference: Polysome profiles observed immediately after eIF5A depletion are diagnostic for a role in initiation. This discrepancy is discussed.

Dependence of proteasome processing rate on substrate unfolding.

Protein degradation by eukaryotic proteasomes is a multi-step process involving substrate recognition, ATP-dependent unfolding, translocation into the proteolytic core particle, and finally proteolysis. To date, most investigations of proteasome function have focused on the first and the last steps in this process. Here we examine the relationship between the stability of a folded protein domain and its degradation rate. Test proteins were targeted to the proteasome independently of ubiquitination by directly tethering them to the protease. Degradation kinetics were compared for test protein pairs whose stability was altered by either point mutation or ligand binding, but were otherwise identical. In both intact cells and in reactions using purified proteasomes and substrates, increased substrate stability led to an increase in substrate turnover time. The steady-state time for degradation ranged from ∼5 min (dihydrofolate reductase) to 40 min (I27 domain of titin). ATP turnover was 110/min./proteasome, and was not markedly changed by substrate. Proteasomes engage tightly folded substrates in multiple iterative rounds of ATP hydrolysis, a process that can be rate-limiting for degradation.