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Kumar 2021 JCI Insight

From Bioblast
Publications in the MiPMap
Kumar A, Welch N, Mishra S, Bellar A, Silva RN, Li L, Singh SS, Sharkoff M, Kerr A, Chelluboyina AK, Sekar J, Attaway AH, Hoppel C, Willard B, Davuluri G, Dasarathy S (2021) Metabolic reprogramming during hyperammonemia targets mitochondrial function and postmitotic senescence . JCI Insight 6:e154089.

Β» PMID: 34935641 Open Access

Kumar Avinash, Welch Nicole, Mishra Saurabh, Bellar Annette, Nasciemento Silva Rafaella, Li Ling, Singh Shashi Shekhar, Sharkoff Mary, Kerr Alexis, Chelluboyina Aruna Kumar, Sekar Jinendiran, Attaway Army H, Hoppel Charles, Willard Belinda, Davuluri Gangarao, Dasarathy Srinivasan (2021) JCI Insight

Abstract: Ammonia is a cytotoxic metabolite with pleiotropic molecular and metabolic effects, including senescence induction. During dysregulated ammonia metabolism, which occurs in chronic diseases, skeletal muscle becomes a major organ for nonhepatocyte ammonia uptake. Muscle ammonia disposal occurs in mitochondria via cataplerosis of critical intermediary metabolite Ξ±-ketoglutarate, a senescence-ameliorating molecule. Untargeted and mitochondrially targeted data were analyzed by multiomics approaches. These analyses were validated experimentally to dissect the specific mitochondrial oxidative defects and functional consequences, including senescence. Responses to ammonia lowering in myotubes and in hyperammonemic portacaval anastomosis rat muscle were studied. Whole-cell transcriptomics integrated with whole-cell, mitochondrial, and tissue proteomics showed distinct temporal clusters of responses with enrichment of oxidative dysfunction and senescence-related pathways/proteins during hyperammonemia and after ammonia withdrawal. Functional and metabolic studies showed defects in electron transport chain complexes I, III, and IV; loss of supercomplex assembly; decreased ATP synthesis; increased free radical generation with oxidative modification of proteins/lipids; and senescence-associated molecular phenotype-increased Ξ²-galactosidase activity and expression of p16INK, p21, and p53. These perturbations were partially reversed by ammonia lowering. Dysregulated ammonia metabolism caused reversible mitochondrial dysfunction by transcriptional and translational perturbations in multiple pathways with a distinct skeletal muscle senescence-associated molecular phenotype. β€’ Keywords: Cell Biology, Cellular senescence, Hepatology, Mitochondria, Skeletal muscle β€’ Bioblast editor: Plangger M


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HRR: Oxygraph-2k 

2022-01