The key challenge addressed in this proposal is to develop a means to harness the power of molecular biology to define therapeutic targets for brain disease. This treatment-oriented approach combines the urgency of a practicing neurologist with the knowledge and technology modern science brings to neuroscience. From the basic science perspective, understanding the fundamental root mechanism of disease is an uncompromising goal. From the neurologist's perspective, the perfect cannot be the enemy of the good, leading to five basic points: Success to date in the treatment of brain disease offers a key lesson in focus. Treatments target accessible molecules, and this will dictate how we focus big data analysis. Human neurologic disease is complicated. The best model system for understanding neurologic disorders is the human; studies of human brain material must be integral to developing new treatments. Regardless of the cause of brain disease?and current neuroscience is appropriately focused on tracing ?genetic? (DNA) etiologies?the manifestations of such defects are mediated by the stoichiometry, distribution and variability of cell-specific RNA regulation and its consequent effects on proteins within affected cells. Different cell types contribute to different brain disorders, but the difference between individual cells of any one type is unknown. The differences between them are manifest at the level of RNA, not DNA. The quantity, quality (isoforms) and distribution of targets (e.g., receptors) are enormous. The unique spectrum of diversity of an individual cell type?neurons, astrocytes or microglial cells?is unknown, more so when comparing diseased and normal brain. Using a variety of new strategies, we will study RNA regulation in individual cell types. Bridging these points together requires new methods and computational approaches. The net result of contrasting RNA regulation in individual human cell types in health and disease will uncover otherwise hidden cell type-specific targets for therapeutics.

Public Health Relevance

Neurologists need to know the molecular basis of disease in order to help find ways to treat patients. We propose to develop and harness new technologies to identify RNA differences that predict how to target brain disease. The strategy combines new single cell methods, computational science and a focused approach to treatment to identify druggable targets by cell type and subcellular localization.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Unknown (R35)
Project #
5R35NS097404-04
Application #
9825566
Study Section
Special Emphasis Panel (ZNS1)
Program Officer
Mamounas, Laura
Project Start
2016-12-01
Project End
2024-11-30
Budget Start
2019-12-01
Budget End
2020-11-30
Support Year
4
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Rockefeller University
Department
Internal Medicine/Medicine
Type
Graduate Schools
DUNS #
071037113
City
New York
State
NY
Country
United States
Zip Code
10065
Yuan, Yuan; Xie, Shirley; Darnell, Jennifer C et al. (2018) Cell type-specific CLIP reveals that NOVA regulates cytoskeleton interactions in motoneurons. Genome Biol 19:117
Stephenson, William; Donlin, Laura T; Butler, Andrew et al. (2018) Single-cell RNA-seq of rheumatoid arthritis synovial tissue using low-cost microfluidic instrumentation. Nat Commun 9:791
Ule, Jernej; Hwang, Hun-Way; Darnell, Robert B (2018) The Future of Cross-Linking and Immunoprecipitation (CLIP). Cold Spring Harb Perspect Biol 10:
Moore, Michael J; Blachere, Nathalie E; Fak, John J et al. (2018) ZFP36 RNA-binding proteins restrain T cell activation and anti-viral immunity. Elife 7:
Hwang, Hun-Way; Saito, Yuhki; Park, Christopher Y et al. (2017) cTag-PAPERCLIP Reveals Alternative Polyadenylation Promotes Cell-Type Specific Protein Diversity and Shifts Araf Isoforms with Microglia Activation. Neuron 95:1334-1349.e5
Ke, Shengdong; Pandya-Jones, Amy; Saito, Yuhki et al. (2017) m6A mRNA modifications are deposited in nascent pre-mRNA and are not required for splicing but do specify cytoplasmic turnover. Genes Dev 31:990-1006
Korb, Erica; Herre, Margaret; Zucker-Scharff, Ilana et al. (2017) Excess Translation of Epigenetic Regulators Contributes to Fragile X Syndrome and Is Alleviated by Brd4 Inhibition. Cell 170:1209-1223.e20
Luna, Joseph M; Barajas, Juan M; Teng, Kun-Yu et al. (2017) Argonaute CLIP Defines a Deregulated miR-122-Bound Transcriptome that Correlates with Patient Survival in Human Liver Cancer. Mol Cell 67:400-410.e7