Mitochondrial diseases comprise a heterogeneous group of genetically inherited disorders resulting from mutations in mitochondrial or nuclear encoded genes that cause failures in mitochondrial energetic and metabolic function which, in the most severe cases, will lead to death. Incidence rates of 1:5000 have been reported placing mitochondrial disorders as one of the most commonly inherited human diseases. To date, there are no effective treatments, and as such, represents an urgent medical need to develop new technologies and platforms to uncover novel therapeutic opportunities. Identification of specific targets and drugs that increase mitochondrial bioenergetics can be of therapeutic value to treat mitochondrial diseases. To address this goal, we performed an unbiased high-throughput chemical and complementary genome-wide CRISPR editing screen in trans-mitochondrial hybrid (cybrids) cells harboring a mutation in a mitochondrial encoded complex I subunit. The IBET 525762A bromodomain and extraterminal domain (IBET) inhibitor emerged as the most potent compound to enhance the oxidative phosphorylation (OXPHOS) capacity in these cells. IBET 525762A functionally targets bromodomain-containing protein 4 (Brd4) and its inhibition enhances oxidative phosphorylation genes, protein, and activity. Furthermore, Brd4 inhibition promotes human cybrid cell survival under high energetic demands and protects against galactose-induced cell death (a standard clinical assay to identify mitochondrial defects). To explore the mechanism detailing how Brd4 inhibition controls mitochondrial bioenergetics, a series of comprehensive biochemical and metabolic analysis will be performed.
Two specific aims will be assessed. In the first aim, we would like to explore on a molecular and functional level how Brd4 controls mitochondrial gene expression programs in cybrid cells. We will map the occupancy and interacting partners of Brd4 to gain insights into this mechanism.
Aim 2 will assess the cellular, metabolic, and bioenergetic effects of Brd4 inhibition in other human cybrid and patient-derived fibroblasts cells with diverse mitochondrial disorders. We will determine if IBET 525762A-mediated increases in the OXPHOS program can persist to other cellular models of mitochondrial disease. The results from the proposed studies will improve our understanding of how Brd4 inhibition restores mitochondrial energetic function in mitochondrial disease cellular models. This will lead to the development of effective therapies for patients with mitochondrial disorders.

Public Health Relevance

Mitochondrial diseases are a diverse group of genetically inherited disorders that occur due to mutations in mitochondrial or nuclear DNA that cause failures in the mitochondria's ability to make ATP and to perform its other energetic and metabolic functions. Incidence rates of 1:5000 have been reported placing mitochondrial disorders as one of the most commonly inherited human diseases and to date there is no cure or effective therapy. Identification of specific targets and drugs that could increase mitochondrial bioenergetics and improve the ability for the mitochondria to generate ATP can be of therapeutic value to treat mitochondrial disorders.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Postdoctoral Individual National Research Service Award (F32)
Project #
1F32GM121014-01A1
Application #
9258917
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Barski, Oleg
Project Start
2017-06-01
Project End
2018-05-31
Budget Start
2017-06-01
Budget End
2018-05-31
Support Year
1
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Dana-Farber Cancer Institute
Department
Type
DUNS #
076580745
City
Boston
State
MA
Country
United States
Zip Code
02215
Soustek, Meghan S; Balsa, Eduardo; Barrow, Joeva J et al. (2018) Inhibition of the ER stress IRE1? inflammatory pathway protects against cell death in mitochondrial complex I mutant cells. Cell Death Dis 9:658