Proteins Resident in the Er
Sambrook, Joseph F.   
University of Texas Sw Medical Center Dallas, Dallas, TX, United States

The endoplasmic reticulum, the first organelle in the secretory pathway, carries out a multiplicity of functions including folding and glycosylation of newly-synthesized polypeptides, assembly of multimeric proteins, storage of Ca++ ions and packaging of secretory proteins into vesicles that are targeted to the next organelle in the secretory chain. The long-term goal of the investigators work is to understand how each of these individual functions is accomplished and how they are coordinated in a way that allows them to be carried coherently. The proposed work couples the advantages of two experimental eukaryotic systems: mammalian cells (or in vitro systems derived from them) for biochemical analysis, and the yeast Saccharomyces cerevisae for genetic analysis. The investigators specific aims are: to analyze the relationship between the structure and function of BiP, the chief chaperone protein of the ER. Using the recently-elucidated three-dimensional structure of N-terminal domain of a closely-related protein (hsc70) as a guide, the investigators will analyze the biochemical and physiological properties of a series of site-directed mutants that (i) alter the amino acids involved in ATP binding and hydrolysis (ii) prevent movement of the hinge region of the molecule (iii) eliminate Ca++ binding sites (iv) modify the sequences within the substrate recognition domain. To analyze in detail the physiological and biochemical properties of a novel form of peptidyl prolyl isomerase (sig-PPI) that appears to be located in the ER of yeast. To explore the role of Ca++ in the maintenance of ER integrity and function. In particular, Dr. Sambrook will investigate the biochemical and physiological behavior of yeast cells carrying mutations in genes coding for three proteins (Ca++ ATPase, calreticulin, and the receptor for Ins (1,4,5)P3 that are thought to be involved in the storage of Ca++ in the ER and in the flux of Ca++ across the ER membrane.