Informed studies of gene expression have allowed us to decipher fundamental elements of how cells work and to develop targeted treatments for disease, but these studies have depended on rigid assumptions for how genomic blueprints should be interpreted. Until recently, it was not possible to experimentally determine which genomic regions encode proteins, and computational approaches for systematic identification of such regions have historically been limited to Open Reading Frames (ORFs) that were above 100 codons. Recent experimental data, including my own, challenge this choice with evidence for pervasive, regulated translation of shorter ORFs (sORFs). A small number of sORF-encoded peptides have been found to have important and specific cellular roles, but these examples were investigated in an ad hoc manner and the functions of the thousands of sORFs recently identified as translated in large-scale studies remain unexplored. I propose that cellular and molecular significance for sORFs can be unraveled through integrated, complementary, and highly parallel functional screening in cells undergoing meiosis, the conserved process of cellular differentiation that produces gametes. I identified over 2500 sORFs that undergo regulated translation in meiotic budding yeast cells, all of which are currently functionally mysterious. The goal of this proposal is to define roles for these new factors, with a broader goal of informing on the types of biological function that can be mediated by the short translated regions that we now know to be prevalent in eukaryotic cells. Meiosis is a system that is well suited to multilayered and systematic discovery of in vivo sORF function, as it consists of many precisely timed and benchmarked stages, driven by intricate and layered control of gene expression. Proper meiotic progression is important for fertility and health, and meiotic errors result in disorders, such as Down's Syndrome, through mechanisms that we do not yet understand. I anticipate that determining function for the set of meiotic sORFs will illuminate new molecular aspects of this important biological process by defining roles for a large, active portion of the genome that has been overlooked. By integrating layered genomic, functional, and computational data, these approaches leverage our knowledge of the many defined stages of meiosis to uncover specific function for a large new class of cellular factors. Further, my findings will enable distillation of general principles in peptide function and genome coding. This work has the potential to change the way that we think about eukaryotic signaling and gene function, with broad importance for our understanding of the fundamental mechanisms underlying normal and disease states.

Public Health Relevance

Healthy and diseased cells are defined by the set of genes that they turn on and off. Genome sequences have been valuable in allowing us to identify genes and then measure their functional (or sometimes dysfunctional) products, but we have historically had a very rigid definition of what types of regions constitute genes. Recently, it ha become clear that thousands of shorter genes exist and here I propose a set of strategies to dissect their function with the goal of understanding how genomes convert information from linear DNA sequences to functional protein products.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
NIH Director’s New Innovator Awards (DP2)
Project #
1DP2GM119138-01
Application #
8952119
Study Section
Special Emphasis Panel ()
Program Officer
Hamlet, Michelle R
Project Start
2015-09-30
Project End
2020-05-31
Budget Start
2015-09-30
Budget End
2020-05-31
Support Year
1
Fiscal Year
2015
Total Cost
$2,355,000
Indirect Cost
$855,000
Name
University of California Berkeley
Department
Biochemistry
Type
Schools of Arts and Sciences
DUNS #
124726725
City
Berkeley
State
CA
Country
United States
Zip Code
94704
Eisenberg, Amy Rose; Higdon, Andrea; Keskin, Abdurrahman et al. (2018) Precise Post-translational Tuning Occurs for Most Protein Complex Components during Meiosis. Cell Rep 25:3603-3617.e2
Hollerer, Ina; Higdon, Andrea; Brar, Gloria A (2018) Strategies and Challenges in Identifying Function for Thousands of sORF-Encoded Peptides in Meiosis. Proteomics 18:e1700274
Powers, Emily Nicole; Brar, Gloria Ann (2018) m6A and eIF2?-? Team Up to Tackle ATF4 Translation during Stress. Mol Cell 69:537-538
Van Dalfsen, Kelsey Marie; Hodapp, Stefanie; Keskin, Abdurrahman et al. (2018) Global Proteome Remodeling during ER Stress Involves Hac1-Driven Expression of Long Undecoded Transcript Isoforms. Dev Cell 46:219-235.e8
Cheng, Ze; Otto, George Maxwell; Powers, Emily Nicole et al. (2018) Pervasive, Coordinated Protein-Level Changes Driven by Transcript Isoform Switching during Meiosis. Cell 172:910-923.e16