Mitochondrial disease, defined as a group of disorders due to defects in the respiratory chain/oxidative-phosphorylation system (OxPhos), comprises an important group of pathologies that are challenging to study and treat, as they are among the most heterogeneous human conditions at every level: clinical, biochemical, and genetic. Mitochondria are under dual genetic control, dependent on both nuclear DNA (nDNA) and mitochondrial DNA (mtDNA). Pathogenic mutations in genes encoded by both genomes give rise to mitochondrial disease, many of which are neurodegenerative disorders that typically are both devastating and ultimately fatal. Mutations in mtDNA genes affect structural subunits of the OxPhos system, whereas mutations in nDNA genes are more numerous and diverse, as they encode not only a large number of OxPhos subunits but also factors needed for the proper synthesis, assembly, and functioning of the OxPhos machinery. We recently discovered that in cells from patients with mitochondrial disease there is a significant disruption in the intimate communication, both physical and biochemical, between mitochondria and endoplasmic reticulum (ER) at mitochondria-associated ER membranes (MAM). MAM is a central locus for maintaining cellular cholesterol, phospholipid, and calcium homeostasis, as well as regulating mitochondrial bioenergetics and dynamics (organellar fusion, fission, and positioning). Based on this finding, we hypothesize that reductions in oxidative energy metabolism can disrupt ER-mitochondrial communication, with serious consequences for cell survivability that go well beyond that of reduced ATP output. The objectives of this application - and our Specific Aims - are thus threefold: (1) to deduce the genetic and biochemical circumstances under which OxPhos deficits affect MAM (the phenotypic landscape), by analyzing cells from patients with known mutations in nDNA and mtDNA causing OxPhos deficiency, and by perturbing bioenergetics with specific OxPhos toxins; (2) to gain insight into the mechanism by which this occurs, using both biased (i.e. targeted) and unbiased approaches to identify OxPhos-related factors that affect ER-mitochondrial connectivity; and (3) to determine if we can use either genetic or pharmacological approaches to improve ER-mitochondrial communication in cells with genetically-compromised bioenergetics, thereby revealing latent OxPhos potential (i.e. improved OxPhos output and efficiency) and increasing bioenergetic output, even in cells with a high mutation load. Our discovery of an OxPhos-MAM connection has revealed a hitherto unknown pathogenetic role of altered inter-organellar communication in mitochondrial disease. In turn, this has opened up a new way of thinking about the pathogenesis and treatment of mitochondrial disease. A therapeutic strategy based on fixing ER-mitochondrial connectivity to re-normalize MAM function will likely be generalizable to a large number of mitochondrial disorders.

Public Health Relevance

Mitochondria are tiny bacterium-sized organelles, located in essentially every cell of the body, that play a critical and central role in producing approximately almost all of the energy in the body; if something goes wrong with the machinery running this 'bioenergetic' factory, cells, and especially those with high energy demands, such as brain, heart, and muscle, begin to 'run out of gas,' and will eventually die. We have discovered that in cells from patients with defective mitochondrial energy production (i.e. mitochondrial disease), there is a 'ripple effect' on the rest of the cell that is mediated by a disruption in the physical connections between mitochondria and endoplasmic reticulum (ER), an organelle that is required for numerous functions, including the distribution of proteins throughout the cell, lipid metabolism, calcium metabolism, and responses to stress. We propose here to study how reduced energy production in mitochondrial disease patients alters ER-mitochondrial connectivity and communication, with the ultimate goal of using this knowledge to 'reverse' the connectivity defect as a way to treat these devastating and often fatal disorders.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
1R01NS117538-01
Application #
10033008
Study Section
Neural Oxidative Metabolism and Death Study Section (NOMD)
Program Officer
Morris, Jill A
Project Start
2020-09-01
Project End
2025-06-30
Budget Start
2020-09-01
Budget End
2021-06-30
Support Year
1
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Columbia University (N.Y.)
Department
Neurology
Type
Schools of Medicine
DUNS #
621889815
City
New York
State
NY
Country
United States
Zip Code
10032