Your search keyword '"Balnis, Joseph"' showing total 4 results

1. Succinate dehydrogenase-complex II regulates skeletal muscle cellular respiration and contractility but not muscle mass in genetically induced pulmonary emphysema.

Author

Balnis, Joseph, Tufts, Ankita, Jackson, Emily L., Drake, Lisa A., Singer, Diane V., Lacomis, David, Chun Geun Lee, Elias, Jack A., Doles, Jason D., Maher III, L. James, Jen, Annie, Coon, Joshua J., Jourd'heuil, David, Singer, Harold A., Vincent, Catherine E., and Jaitovich, Ariel

Subjects

*PULMONARY emphysema, *CELL respiration, *OXYGEN consumption, *MUSCLE mass, *SKELETAL muscle, *SUCCINATE dehydrogenase, *MUSCULAR atrophy

Abstract

Reduced skeletal muscle mass and oxidative capacity coexist in patients with pulmonary emphysema and are independently associated with higher mortality. If reduced cellular respiration contributes to muscle atrophy in that setting remains unknown. Using a mouse with genetically induced pulmonary emphysema that recapitulates muscle dysfunction, we found that reduced activity of succinate dehydrogenase (SDH) is a hallmark of its myopathic changes. We generated an inducible, muscle-specific SDH knockout mouse that demonstrates lower mitochondrial oxygen consumption, myofiber contractility, and exercise endurance. Respirometry analyses show that in vitro complex I respiration is unaffected by loss of SDH subunit C in muscle mitochondria, which is consistent with the pulmonary emphysema animal data. SDH knockout initially causes succinate accumulation associated with a down-regulated transcriptome but modest proteome effects. Muscle mass, myofiber type composition, and overall body mass constituents remain unaltered in the transgenic mice. Thus, while SDH regulates myofiber respiration in experimental pulmonary emphysema, it does not control muscle mass or other body constituents. [ABSTRACT FROM AUTHOR]

Published

2024

2. Deaccelerated Myogenesis and Autophagy in Genetically Induced Pulmonary Emphysema.

Author

Balnis, Joseph, Drake, Lisa A., Singer, Diane V., Vincent, Catherine E., Korponay, Tanner C., D'Armiento, Jeanine, Chun Geun Lee, Elias, Jack A., Singer, Harold A., and Jaitovich, Ariel

Subjects

PULMONARY emphysema, MUSCLE mass, MYOGENESIS, AUTOPHAGY, SATELLITE cells, CHRONIC obstructive pulmonary disease

Abstract

Patients with chronic obstructive pulmonary disease (COPD)-pulmonary emphysema often develop locomotor muscle dysfunction, which entails reduced muscle mass and force-generation capacity and is associated with worse outcomes, including higher mortality. Myogenesis contributes to adult muscle integrity during injury-repair cycles. Injurious events crucially occur in the skeletal muscles of patients with COPD in the setting of exacerbations and infections, which lead to acute decompensations for limited periods of time, after which patients typically fail to recover the baseline status they had before the acute event. Autophagy, which is dysregulated in muscles from patients with COPD, is a key regulator of muscle stem-satellite-cells activation and myogenesis, yet very little research has so far mechanistically investigated the role of autophagy dysregulation in COPD muscles. Using a genetically inducible interleukin- 13-driven pulmonary emphysema model leading to muscle dysfunction, and confirmed with a second genetic animal model, we found a significant myogenic dysfunction associated with the reduced proliferative capacity of satellite cells. Transplantation experiments followed by lineage tracing suggest that an intrinsic defect in satellite cells, and not in the COPD environment, plays a dominant role in the observed myogenic dysfunction. RNA sequencing analysis and direct observation of COPD mice satellite cells suggest dysregulated autophagy. Moreover, while autophagy flux experiments with bafilomycin demonstrated deacceleration of autophagosome turnover in COPD mice satellite cells, spermidine-induced autophagy stimulation leads to a higher replication rate and myogenesis in these animals. Our data suggest that pulmonary emphysema causes disrupted myogenesis, which could be improved with stimulation of autophagy and satellite cells activation, leading to an attenuated muscle dysfunction. [ABSTRACT FROM AUTHOR]

Published

2022

3. Hypercapnia-Driven Skeletal Muscle Dysfunction in an Animal Model of Pulmonary Emphysema Suggests a Complex Phenotype.

Author

Balnis, Joseph, Lee, Chun Geun, Elias, Jack A., and Jaitovich, Ariel

Subjects

PULMONARY emphysema, SKELETAL muscle, OBSTRUCTIVE lung diseases, ANIMAL models in research, MUSCLE mass

Abstract

Patients with chronic pulmonary conditions such as chronic obstructive pulmonary disease (COPD) often develop skeletal muscle dysfunction, which is strongly and independently associated with poor outcomes including higher mortality. Some of these patients also develop chronic CO2 retention, or hypercapnia, which is also associated with worse prognosis. While muscle dysfunction in these settings involve reduction of muscle mass and disrupted fibers' metabolism leading to suboptimal muscle work, mechanistic research in the field has been limited by the lack of adequate animal models. Over the last years, we have established a rodent model of COPD-induced skeletal muscle dysfunction that allowed a disaggregated interrogation of the cellular and physiological effects driven by COPD from the ones unique to hypercapnia. We found that while COPD and hypercapnia synergistically contribute to muscle atrophy, they are antagonistic processes regarding fibers respiratory capacity. We propose that AMP-activated protein kinase (AMPK) is a crucial regulator of CO2 signaling in hypercapnic muscles, which leads to both net protein catabolism and improved mitochondrial respiration to support a transition into a substrate-rich, fuel-efficient metabolic mode that allows muscle cells cope with the CO2 toxicity. [ABSTRACT FROM AUTHOR]

Published

2020

4. IL-13-driven pulmonary emphysema leads to skeletal muscle dysfunction attenuated by endurance exercise.

Author

Balnis, Joseph, Korponay, Tanner C., Vincent, Catherine E., Singer, Diane V., Adam, Alejandro P., Lacomis, David, Chun Geun Lee, Elias, Jack A., Singer, Harold A., and Jaitovich, Ariel

Subjects

PULMONARY emphysema, SKELETAL muscle, OBSTRUCTIVE lung diseases, SUCCINATE dehydrogenase, MUSCLE mass

Abstract

Patients with chronic obstructive pulmonary disease (COPD) usually develop skeletal muscle dysfunction, which represents a major comorbidity in these patients and is strongly associated with mortality and other poor outcomes. Although clinical data indicates that accelerated protein degradation and metabolic disruption are common associations of muscle dysfunction in COPD, there is very limited data on the mechanisms regulating the process, in part, due to the lack of research performed on a validated animal model of pulmonary emphysema. This model deficiency complicates the translational value of data generated with highly reductionist settings. Here, we use an established transgenic animal model of COPD based on inducible IL-13-driven pulmonary emphysema (IL-13TG) to interrogate the mechanisms of skeletal muscle dysfunction. Skeletal muscles from these emphysematous mice develop most features present in COPD patients, including atrophy, decreased oxygen consumption, and reduced force-generation capacity. Analysis of muscle proteome indicates downregulation of succinate dehydrogenase C (SDH-C), which correlates with reduced enzymatic activity, also consistent with previous clinical observations. Ontology terms identified with human data, such as ATP binding/bioenergetics are also downregulated in this animal's skeletal muscles. Moreover, chronic exercise can partially restore muscle mass, metabolic and force-generation capacity, and SDH activity in COPD mice. We conclude that this animal model of COPD/emphysema is an adequate platform to further investigate mechanisms of muscle dysfunction in this setting and demonstrates multiple approaches that can be used to address specific mechanisms regulating this process. [ABSTRACT FROM AUTHOR]

Published

2020