Roles of Human elF1 in Translation Preinitiation Complex Assembly
Luna, Rafael E.   
Harvard University, Boston, MA, United States

Based on studies in yeast Saccharomyces cerevisiae, the eukaryotic translation initiation factor (elF) 5 has been shown to serve a critical role in the assembly of an important intermediate in the 43S pre-initiation complex via the formation of multiple binding interfaces mediated by its carboxyl terminal domain (elF5-CTD). This grant proposes investigations to determine the structural mechanisms involved in the formation of the human elF1/elF5-CTD complex, which is an important step in the assembly of the translation pre-initiation complex. Objective/Hypothesis: Preliminary studies in our laboratory indicate that elF1 and elF5-CTD interact and form a complex. Utilizing NMR spectroscopy, we are currently determining the mutual binding interface of the elF1/elF5-CTD complex. This grant proposes investigations to determine the multiple binding-interfaces of the elF1/elF5-CTD complex with components of the human pre-initiation complex. This novel complex mediates an important step in the eukaryotic translation initiation process. In order to investigate the structural role of the elF1/elF5-CTD sub-complex within the pre-initiation complex, we will address the following specific aims: 1.) Map the mutual binding interface of the human elF1/elF5 complex and determine its structure. 2.) Characterize the interaction of human elF5-CTD and elF1/elF5- CTD complex with elF2-beta and elF4G. Study Design: In order to tackle the multiple binding-interface of the elF1/elF5-CTD complex, the scope of this grant will encompass the utilization of nuclear magnetic resonance (NMR) spectroscopy. We will optimize conditions for NMR chemical shift mapping of the multiple binding-interface of the elF1/elF5-CTD complex. An in vitro reconstitution system involving purified proteins in which one component is 15N-labeled (e.g. elF5-CTD) while in the presence of its unlabeled binding partners (e.g. elF1 and elF2-beta). The mapping of the multiple faces of the human elF1/elF5 complex will give an invaluable insight into the assembly the human translation pre-initiation complex. Insights into the structural interactions of the elF1/elF5-CTD sub-complex could lead to the future development of small molecule inhibitors to modulate human translation initiation leading to novel, robust pharmaceutical drugs to treat cancer. ? ? ?