Your search keyword '"Fernández-Del-Rio, Lucía"' showing total 7 results

1. Restoration of lysosomal acidification rescues autophagy and metabolic dysfunction in non-alcoholic fatty liver disease

Author

Zeng, Jialiu, Acin-Perez, Rebeca, Assali, Essam A, Martin, Andrew, Brownstein, Alexandra J, Petcherski, Anton, Fernández-del-Rio, Lucía, Xiao, Ruiqing, Lo, Chih Hung, Shum, Michaël, Liesa, Marc, Han, Xue, Shirihai, Orian S, and Grinstaff, Mark W

Subjects

Biochemistry and Cell Biology, Medicinal and Biomolecular Chemistry, Chemical Sciences, Biological Sciences, Digestive Diseases, Liver Disease, Nutrition, Chronic Liver Disease and Cirrhosis, 2.1 Biological and endogenous factors, Aetiology, Oral and gastrointestinal, Mice, Animals, Non-alcoholic Fatty Liver Disease, Autophagy, Liver, Lysosomes, Hydrogen-Ion Concentration

Abstract

Non-alcoholic fatty liver disease (NAFLD) is the most common liver disease in the world. High levels of free fatty acids in the liver impair hepatic lysosomal acidification and reduce autophagic flux. We investigate whether restoration of lysosomal function in NAFLD recovers autophagic flux, mitochondrial function, and insulin sensitivity. Here, we report the synthesis of novel biodegradable acid-activated acidifying nanoparticles (acNPs) as a lysosome targeting treatment to restore lysosomal acidity and autophagy. The acNPs, composed of fluorinated polyesters, remain inactive at plasma pH, and only become activated in lysosomes after endocytosis. Specifically, they degrade at pH of ~6 characteristic of dysfunctional lysosomes, to further acidify and enhance the function of lysosomes. In established in vivo high fat diet mouse models of NAFLD, re-acidification of lysosomes via acNP treatment restores autophagy and mitochondria function to lean, healthy levels. This restoration, concurrent with reversal of fasting hyperglycemia and hepatic steatosis, indicates the potential use of acNPs as a first-in-kind therapeutic for NAFLD.

Published

2023

2. Genetic screening reveals phospholipid metabolism as a key regulator of the biosynthesis of the redox-active lipid coenzyme Q.

Author

Ayer, Anita, Fazakerley, Daniel J, Suarna, Cacang, Maghzal, Ghassan J, Sheipouri, Diba, Lee, Kevin J, Bradley, Michelle C, Fernández-Del-Rio, Lucía, Tumanov, Sergey, Kong, Stephanie My, van der Veen, Jelske N, Yang, Andrian, Ho, Joshua WK, Clarke, Steven G, James, David E, Dawes, Ian W, Vance, Dennis E, Clarke, Catherine F, Jacobs, René L, and Stocker, Roland

Subjects

Coenzyme Q, Insulin resistance, Mitochondria, PEMT, Reactive oxygen species, S-adenosylhomocysteine, S-adenosylmethionine, Animals, Genetic Testing, Mice, Mitochondrial Diseases, Oxidation-Reduction, Phosphatidylethanolamine N-Methyltransferase, Phospholipids, Ubiquinone, Genetics, Nutrition, 5.1 Pharmaceuticals, Metabolic and endocrine, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Pharmacology and Pharmaceutical Sciences

Abstract

Mitochondrial energy production and function rely on optimal concentrations of the essential redox-active lipid, coenzyme Q (CoQ). CoQ deficiency results in mitochondrial dysfunction associated with increased mitochondrial oxidative stress and a range of pathologies. What drives CoQ deficiency in many of these pathologies is unknown, just as there currently is no effective therapeutic strategy to overcome CoQ deficiency in humans. To date, large-scale studies aimed at systematically interrogating endogenous systems that control CoQ biosynthesis and their potential utility to treat disease have not been carried out. Therefore, we developed a quantitative high-throughput method to determine CoQ concentrations in yeast cells. Applying this method to the Yeast Deletion Collection as a genome-wide screen, 30 genes not known previously to regulate cellular concentrations of CoQ were discovered. In combination with untargeted lipidomics and metabolomics, phosphatidylethanolamine N-methyltransferase (PEMT) deficiency was confirmed as a positive regulator of CoQ synthesis, the first identified to date. Mechanistically, PEMT deficiency alters mitochondrial concentrations of one-carbon metabolites, characterized by an increase in the S-adenosylmethionine to S-adenosylhomocysteine (SAM-to-SAH) ratio that reflects mitochondrial methylation capacity, drives CoQ synthesis, and is associated with a decrease in mitochondrial oxidative stress. The newly described regulatory pathway appears evolutionary conserved, as ablation of PEMT using antisense oligonucleotides increases mitochondrial CoQ in mouse-derived adipocytes that translates to improved glucose utilization by these cells, and protection of mice from high-fat diet-induced insulin resistance. Our studies reveal a previously unrecognized relationship between two spatially distinct lipid pathways with potential implications for the treatment of CoQ deficiencies, mitochondrial oxidative stress/dysfunction, and associated diseases.

Published

2021

3. Novel Small-Molecule Improves Mitochondrial Function and Mitophagy in a Complex III Deficiency Model

Author

Fernández-del-Rio, Lucía, Eastes, Andrea, Oliveira, Matheus P., Erion, Karel, Pacheco, David R.F., Garza, Jasmine, Dugan, Matthew, Kantor, Sophie, Gauhar, Iman, Ma, Philip, Wanagat, Jonathan, Rodgers, Kathleen, Gaffney, Kevin, Wang, Amy, Liesa-Roig, Marc, Benincá, Cristiane, and Shirihai, Orian

Published

2024

4. Kaempferol increases levels of coenzyme Q in kidney cells and serves as a biosynthetic ring precursor

Author

Fernández-del-Río, Lucía, Nag, Anish, Gutiérrez Casado, Elena, Ariza, Julia, Awad, Agape M., Joseph, Akil I., Kwon, Ohyun, Verdin, Eric, de Cabo, Rafael, Schneider, Claus, Torres, Jorge Z., Burón, María I., Clarke, Catherine F., and Villalba, José M.

Published

2017

5. Genetic screening reveals phospholipid metabolism as a key regulator of the biosynthesis of the redox-active lipid coenzyme Q

Author

Ayer, Anita, primary, Fazakerley, Daniel J., additional, Suarna, Cacang, additional, Maghzal, Ghassan J., additional, Sheipouri, Diba, additional, Lee, Kevin J., additional, Bradley, Michelle C., additional, Fernández-del-Rio, Lucía, additional, Tumanov, Sergey, additional, Kong, Stephanie MY., additional, van der Veen, Jelske N., additional, Yang, Andrian, additional, Ho, Joshua W.K., additional, Clarke, Steven G., additional, James, David E., additional, Dawes, Ian W., additional, Vance, Dennis E., additional, Clarke, Catherine F., additional, Jacobs, René L., additional, and Stocker, Roland, additional

Published

2021

6. Genetic screening reveals phospholipid metabolism as a key regulator of the biosynthesis of the redox-active lipid coenzyme Q

Author

Ayer, Anita, Fazakerley, Daniel J, Suarna, Cacang, Maghzal, Ghassan J, Sheipouri, Diba, Lee, Kevin J, Bradley, Michelle C, Fernández-Del-Rio, Lucía, Tumanov, Sergey, Kong, Stephanie My, Van Der Veen, Jelske N, Yang, Andrian, Ho, Joshua WK, Clarke, Steven G, James, David E, Dawes, Ian W, Vance, Dennis E, Clarke, Catherine F, Jacobs, René L, and Stocker, Roland

Subjects

S-adenosylmethionine, Mitochondrial Diseases, Ubiquinone, Phosphatidylethanolamine N-Methyltransferase, S-adenosylhomocysteine, food and beverages, Coenzyme Q, Insulin resistance, 3. Good health, Mitochondria, Mice, PEMT, Animals, Genetic Testing, Reactive oxygen species, Oxidation-Reduction, Phospholipids

Abstract

Mitochondrial energy production and function rely on optimal concentrations of the essential redox-active lipid, coenzyme Q (CoQ). CoQ deficiency results in mitochondrial dysfunction associated with increased mitochondrial oxidative stress and a range of pathologies. What drives CoQ deficiency in many of these pathologies is unknown, just as there currently is no effective therapeutic strategy to overcome CoQ deficiency in humans. To date, large-scale studies aimed at systematically interrogating endogenous systems that control CoQ biosynthesis and their potential utility to treat disease have not been carried out. Therefore, we developed a quantitative high-throughput method to determine CoQ concentrations in yeast cells. Applying this method to the Yeast Deletion Collection as a genome-wide screen, 30 genes not known previously to regulate cellular concentrations of CoQ were discovered. In combination with untargeted lipidomics and metabolomics, phosphatidylethanolamine N-methyltransferase (PEMT) deficiency was confirmed as a positive regulator of CoQ synthesis, the first identified to date. Mechanistically, PEMT deficiency alters mitochondrial concentrations of one-carbon metabolites, characterized by an increase in the S-adenosylmethionine to S-adenosylhomocysteine (SAM-to-SAH) ratio that reflects mitochondrial methylation capacity, drives CoQ synthesis, and is associated with a decrease in mitochondrial oxidative stress. The newly described regulatory pathway appears evolutionary conserved, as ablation of PEMT using antisense oligonucleotides increases mitochondrial CoQ in mouse-derived adipocytes that translates to improved glucose utilization by these cells, and protection of mice from high-fat diet-induced insulin resistance. Our studies reveal a previously unrecognized relationship between two spatially distinct lipid pathways with potential implications for the treatment of CoQ deficiencies, mitochondrial oxidative stress/dysfunction, and associated diseases.

7. Genetic screening reveals phospholipid metabolism as a key regulator of the biosynthesis of the redox-active lipid coenzyme Q

Author

Ayer, Anita, Fazakerley, Daniel J, Suarna, Cacang, Maghzal, Ghassan J, Sheipouri, Diba, Lee, Kevin J, Bradley, Michelle C, Fernández-Del-Rio, Lucía, Tumanov, Sergey, Kong, Stephanie My, Van Der Veen, Jelske N, Yang, Andrian, Ho, Joshua W K, Clarke, Steven G, James, David E, Dawes, Ian W, Vance, Dennis E, Clarke, Catherine F, Jacobs, René L, and Stocker, Roland

Subjects

S-Adenosylmethionine, Pemt, S-adenosylhomocysteine, food and beverages, Coenzyme Q, Insulin resistance, Reactive oxygen species, 3. Good health, Mitochondria

Abstract

Mitochondrial energy production and function rely on optimal concentrations of the essential redox-active lipid, coenzyme Q (CoQ). CoQ deficiency results in mitochondrial dysfunction associated with increased mitochondrial oxidative stress and a range of pathologies. What drives CoQ deficiency in many of these pathologies is unknown, just as there currently is no effective therapeutic strategy to overcome CoQ deficiency in humans. To date, large-scale studies aimed at systematically interrogating endogenous systems that control CoQ biosynthesis and their potential utility to treat disease have not been carried out. Therefore, we developed a quantitative high-throughput method to determine CoQ concentrations in yeast cells. Applying this method to the Yeast Deletion Collection as a genome-wide screen, 30 genes not known previously to regulate cellular concentrations of CoQ were discovered. In combination with untargeted lipidomics and metabolomics, phosphatidylethanolamine N-methyltransferase (PEMT) deficiency was confirmed as a positive regulator of CoQ synthesis, the first identified to date. Mechanistically, PEMT deficiency alters mitochondrial concentrations of one-carbon metabolites, characterized by an increase in the S-adenosylmethionine to S-adenosylhomocysteine (SAM-to-SAH) ratio that reflects mitochondrial methylation capacity, drives CoQ synthesis, and is associated with a decrease in mitochondrial oxidative stress. The newly described regulatory pathway appears evolutionary conserved, as ablation of PEMT using antisense oligonucleotides increases mitochondrial CoQ in mouse-derived adipocytes that translates to improved glucose utilization by these cells, and protection of mice from high-fat diet-induced insulin resistance. Our studies reveal a previously unrecognized relationship between two spatially distinct lipid pathways with potential implications for the treatment of CoQ deficiencies, mitochondrial oxidative stress/dysfunction, and associated diseases.