Mitochondrial diseases are heterogeneous genetic disorders caused by respiratory chain (RC) impairment. Attempts to treat mitochondrial diseases have been disappointing so far, mostly due to the lack of defined targets. The leading hypothesis of this application is that mitochondrial disease pathogenesis involves the blockage of crucial steps of the inter-organ amino acid metabolism. We have identified previously unrecognized defects in glutamine metabolism in cells harboring mitochondrial DNA mutations associated with human mitochondrial diseases. We found that the energetic utilization of glutamine through the glutamine-glutamate-?-ketoglutarate pathway was impaired in these cells. We were able to rescue the metabolic defect by supplementation with compounds that bypass the enzymatic blockages. Glutamine is the most abundant and versatile circulating amino acid, mostly synthesized in skeletal muscle and released in the blood where it plays an important role as a carrier of nitrogen, carbon, and energy between organs. The various glutamine-utilization pathways in the body depend on the specialized metabolism of each tissue and play a crucial role in the inter-organs integrated metabolism that regulates metabolites homeostasis. The goal of this application is to define in vivo the altered glutamine pathways and to bypass the metabolic blockages with dietary supplementation, thus identifying new approaches to the therapy of mitochondrial diseases. To this end, we propose the following aims: 1) Metabolites imbalance in the COX10 KO mouse. We will investigate the glutamine utilization and synthesis pathways in vivo in a mouse model of RC defect caused by genetic disruption of cytochrome c oxidase (COX) assembly, resulting in a progressive mitochondriopathy. The levels of relevant metabolites will be determined in plasma and in tissues, and will be correlated with the bioenergetics, redox, acid/base and nitrogen states. The vulnerability of the affected tissues will be evaluated and correlated with disease progression. 2) Dietary supplementation in the COX10 KO mouse. In preliminary studies in vitro, metabolites that effectively bypass metabolic blocks in RC deficient cells have been identified. These metabolites will be supplemented in the diet of the COX10 KO mouse. The specialized metabolism of different tissues, the inter-organ metabolic homeostasis, and the physiological alterations in relation to disease progression will be assessed. The potential preclinical impact o this aim is that it will provide a rationale for clinical trials based on dietary supplementation, using physiological compounds.

Public Health Relevance

Mitochondrial diseases are genetic disorders caused by metabolic impairment and characterized by severe neurological and muscular disorders. Attempts to treat mitochondrial diseases have been disappointing due to the lack of defined targets. We found an abnormal utilization of the amino acids glutamine and glutamate in cells with mitochondrial dysfunction, and supplementation with specific amino acids and derivatives rescued these cells. In order to identify new approaches for the therapy of mitochondrial diseases we will study the altered glutamine pathways in a mouse model of mitochondrial disease and try to bypass the metabolic blockages with dietary supplementation.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21NS084524-01
Application #
8589748
Study Section
Therapeutic Approaches to Genetic Diseases (TAG)
Program Officer
Gwinn, Katrina
Project Start
2013-07-01
Project End
2015-06-30
Budget Start
2013-07-01
Budget End
2014-06-30
Support Year
1
Fiscal Year
2013
Total Cost
$254,250
Indirect Cost
$104,250
Name
Weill Medical College of Cornell University
Department
Neurology
Type
Schools of Medicine
DUNS #
060217502
City
New York
State
NY
Country
United States
Zip Code
10065
Chen, Qiuying; Kirk, Kathryne; Shurubor, Yevgeniya I et al. (2018) Rewiring of Glutamine Metabolism Is a Bioenergetic Adaptation of Human Cells with Mitochondrial DNA Mutations. Cell Metab 27:1007-1025.e5
Gonzalvez, François; D'Aurelio, Marilena; Boutant, Marie et al. (2013) Barth syndrome: cellular compensation of mitochondrial dysfunction and apoptosis inhibition due to changes in cardiolipin remodeling linked to tafazzin (TAZ) gene mutation. Biochim Biophys Acta 1832:1194-206