Your search keyword '"Prosdocimo, Domenick A."' showing total 5 results

1. Kruppel-like factor 15 regulates skeletal muscle lipid flux and exercise adaptation

Author

Haldar, Saptarsi M., Jeyaraj, Darwin, Anand, Priti, Zhu, Han, Lu, Yuan, Prosdocimo, Domenick A., Eapen, Betty, Kawanami, Daiji, Okutsu, Mitsuharu, Brotto, Leticia, Fujioka, Hisashi, Kerner, Janos, Rosca, Mariana G., McGuinness, Owen P., Snow, Rod J., Russell, Aaron P., Gerber, Anthony N., Bai, Xiaodong, Yan, Zhen, Nosek, Thomas M., Brotto, Marco, Hoppel, Charles L., and Jain, Mukesh K.

Published

2012

2. Glucocorticoids enhance muscle endurance and ameliorate Duchenne muscular dystrophy through a defined metabolic program.

Author

Morrison-Nozik, Alexander, Anand, Priti, Han Zhu, Qiming Duan, Sabeh, Mohamad, Prosdocimo, Domenick A., Lemieux, Madeleine E., Nordsborg, Nikolai, Russell, Aaron P., MacRae, Calum A., Gerber, Anthony N., Jain, Mukesh K., and Haldar, Saptarsi M.

Subjects

GLUCOCORTICOIDS, DUCHENNE muscular dystrophy, ERGOGENIC aids, SKELETAL muscle, TRANSCRIPTION factors

Abstract

Classic physiology studies dating to the 1930s demonstrate that moderate or transient glucocorticoid (GC) exposure improves muscle performance. The ergogenic properties of GCs are further evidenced by their surreptitious use as doping agents by endurance athletes and poorly understood efficacy in Duchenne muscular dystrophy (DMD), a genetic muscle-wasting disease. A defined molecular basis underlying these performance-enhancing properties of GCs in skeletal muscle remains obscure. Here, we demonstrate that ergogenic effects of GCs are mediated by direct induction of the metabolic transcription factor KLF15, defining a downstream pathway distinct from that resulting in GC-related muscle atrophy. Furthermore, we establish that KLF15 deficiency exacerbates dystrophic severity and muscle GC-KLF15 signaling mediates salutary therapeutic effects in the mdx mouse model of DMD. Thus, although glucocorticoid receptor (GR)-mediated transactivation is often associated with muscle atrophy and other adverse effects of pharmacologic GC administration, our data define a distinct GR-induced gene regulatory pathway that contributes to therapeutic effects of GCs in DMD through proergogenic metabolic programming. [ABSTRACT FROM AUTHOR]

Published

2015

3. Muscle Krüppel-like factor 15 regulates lipid flux and systemic metabolic homeostasis.

Author

Fan, Liyan, Sweet, David R., Prosdocimo, Domenick A., Vinayachandran, Vinesh, Chan, Ernest R., Zhang, Rongli, Ilkayeva, Olga, Yuan Lu, Keerthy, Komal S., Booth, Chloe E., Newgard, Christopher B., Jain, Mukesh K., and Lu, Yuan

Subjects

*INSULIN sensitivity, *WHITE adipose tissue, *SHORT-chain fatty acids, *FATTY liver, *HOMEOSTASIS, *PROTEIN metabolism, *PROTEINS, *RESEARCH, *SKELETAL muscle, *ANIMAL experimentation, *RESEARCH methodology, *GENETIC disorders, *MEDICAL cooperation, *EVALUATION research, *MITOCHONDRIA, *COMPARATIVE studies, *RESEARCH funding, *LIPID metabolism disorders, *MICE

Abstract

Skeletal muscle is a major determinant of systemic metabolic homeostasis that plays a critical role in glucose metabolism and insulin sensitivity. By contrast, despite being a major user of fatty acids, and evidence that muscular disorders can lead to abnormal lipid deposition (e.g., nonalcoholic fatty liver disease in myopathies), our understanding of skeletal muscle regulation of systemic lipid homeostasis is not well understood. Here we show that skeletal muscle Krüppel-like factor 15 (KLF15) coordinates pathways central to systemic lipid homeostasis under basal conditions and in response to nutrient overload. Mice with skeletal muscle-specific KLF15 deletion demonstrated (a) reduced expression of key targets involved in lipid uptake, mitochondrial transport, and utilization, (b) elevated circulating lipids, (c) insulin resistance/glucose intolerance, and (d) increased lipid deposition in white adipose tissue and liver. Strikingly, a diet rich in short-chain fatty acids bypassed these defects in lipid flux and ameliorated aspects of metabolic dysregulation. Together, these findings establish skeletal muscle control of lipid flux as critical to systemic lipid homeostasis and metabolic health. [ABSTRACT FROM AUTHOR]

Published

2021

4. Loss of Ptpmt1 limits mitochondrial utilization of carbohydrates and leads to muscle atrophy and heart failure in tissue-specific knockout mice.

Author

Hong Zheng, Qianjin Li, Shanhu Li, Zhiguo Li, Brotto, Marco, Weiss, Daiana, Prosdocimo, Domenick, Chunhui Xu, Reddy, Ashruth, Puchowicz, Michelle, Xinyang Zhao, Weitzmann, M. Neale, Jain, Mukesh K., and Cheng-Kui Qu

Subjects

*MUSCULAR atrophy, *MYOCARDIUM, *KNOCKOUT mice, *HEART failure, *CARBOHYDRATES, *SKELETAL muscle, *MITOCHONDRIA

Abstract

While mitochondria in different tissues have distinct preferences for energy sources, they are flexible in utilizing competing substrates for metabolism according to physiological and nutritional circumstances. However, the regulatory mechanisms and significance of metabolic flexibility are not completely understood. Here, we report that the deletion of Ptpmt1, a mitochondria-based phosphatase, critically alters mitochondrial fuel selection - the utilization of pyruvate, a key mitochondrial substrate derived from glucose (the major simple carbohydrate), is inhibited, whereas the fatty acid utilization is enhanced. Ptpmt1 knockout does not impact the development of the skeletal muscle or heart. However, the metabolic inflexibility ultimately leads to muscular atrophy, heart failure, and sudden death. Mechanistic analyses reveal that the prolonged substrate shift from carbohydrates to lipids causes oxidative stress and mitochondrial destruction, which in turn results in marked accumulation of lipids and profound damage in the knockout muscle cells and cardiomyocytes. Interestingly, Ptpmt1 deletion from the liver or adipose tissue does not generate any local or systemic defects. These findings suggest that Ptpmt1 plays an important role in maintaining mitochondrial flexibility and that their balanced utilization of carbohydrates and lipids is essential for both the skeletal muscle and the heart despite the two tissues having different preferred energy sources. [ABSTRACT FROM AUTHOR]

Published

2023

5. Transcription factors KLF15 and PPARδ cooperatively orchestrate genome-wide regulation of lipid metabolism in skeletal muscle.

Author

Fan, Liyan, Sweet, David R., Fan, Erica K., Prosdocimo, Domenick A., Madera, Annmarie, Zhen Jiang, Padmanabhan, Roshan, Haldar, Saptarsi M., Vinayachandran, Vinesh, and Jain, Mukesh K.

Subjects

*METABOLIC regulation, *SKELETAL muscle, *TRANSCRIPTION factors, *KRUPPEL-like factors, *MUSCLE metabolism, *REGULATOR genes, *LIPID metabolism

Abstract

Skeletal muscle dynamically regulates systemic nutrient homeostasis through transcriptional adaptations to physiological cues. In response to changes in the metabolic environment (e.g., alterations in circulating glucose or lipid levels), networks of transcription factors and coregulators are recruited to specific genomic loci to fine-tune homeostatic gene regulation. Elucidating these mechanisms is of particular interest as these gene regulatory pathways can serve as potential targets to treat metabolic disease. The zinc-finger transcription factor Krüppel-like factor 15 (KLF15) is a critical regulator of metabolic homeostasis; however, its genome-wide distribution in skeletal muscle has not been previously identified. Here, we characterize the KLF15 cistrome in vivo in skeletal muscle and find that the majority of KLF15 binding is localized to distal intergenic regions and associated with genes related to circadian rhythmicity and lipid metabolism. We also identify critical interdependence between KLF15 and the nuclear receptor PPARδ in the regulation of lipid metabolic gene programs. We further demonstrate that KLF15 and PPARδ colocalize genome-wide, physically interact, and are dependent on one another to exert their transcriptional effects on target genes. These findings reveal that skeletal muscle KLF15 plays a critical role in metabolic adaptation through its direct actions on target genes and interactions with other nodal transcription factors such as PPARδ. [ABSTRACT FROM AUTHOR]

Published

2022