Hypoxia induces heart regeneration in adult mice

Nakada, Yuji; Canseco, Diana C.; Thet, Suwannee; Abdisalaam, Salim; Asaithamby, Aroumougame; Santos, Cláudia Y.; Shah, Ajay M.; Zhang, Hua; Faber, James E.; Kinter, Michael; Szweda, Luke I.; Xing, Chao; Hu, Zeping; DeBerardinis, Ralph J.; Schiattarella, Gabriele Giacomo; Hill, Joseph A.; Öz, Orhan K.; Lu, Zhigang; Zhang, Cheng Cheng; Kimura, Wataru; Sadek, Hesham A.

doi:10.1038/nature20173

Cited by 545 publications

(507 citation statements)

References 27 publications

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“…Heart samples were prepared on the basis of our standard targeted proteomics approach 19, 20, 21, 22. Whole heart homogenates were used for the analysis.…”

Section: Methodsmentioning

confidence: 99%

Cardiac Insulin Signaling Regulates Glycolysis Through Phosphofructokinase 2 Content and Activity

Humphries

Matsuzaki

Vadvalkar

et al. 2017

JAHA

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BackgroundThe healthy heart has a dynamic capacity to respond and adapt to changes in nutrient availability. Diabetes mellitus disrupts this metabolic flexibility and promotes cardiomyopathy through mechanisms that are not completely understood. Phosphofructokinase 2 (PFK‐2) is a primary regulator of cardiac glycolysis and substrate selection, yet its regulation under normal and pathological conditions is unknown. This study was undertaken to determine how changes in insulin signaling affect PFK‐2 content, activity, and cardiac metabolism.Methods and ResultsStreptozotocin‐induced diabetes mellitus, high‐fat diet feeding, and fasted mice were used to identify how decreased insulin signaling affects PFK‐2 and cardiac metabolism. Primary adult cardiomyocytes were used to define the mechanisms that regulate PFK‐2 degradation. Both type 1 diabetes mellitus and a high‐fat diet induced a significant decrease in cardiac PFK‐2 protein content without affecting its transcript levels. Overnight fasting also induced a decrease in PFK‐2, suggesting it is rapidly degraded in the absence of insulin signaling. An unbiased metabolomic study demonstrated that decreased PFK‐2 in fasted animals is accompanied by an increase in glycolytic intermediates upstream of phosphofructokianse‐1, whereas those downstream are diminished. Mechanistic studies using cardiomyocytes showed that, in the absence of insulin signaling, PFK‐2 is rapidly degraded via both proteasomal‐ and chaperone‐mediated autophagy.ConclusionsThe loss of PFK‐2 content as a result of reduced insulin signaling impairs the capacity to dynamically regulate glycolysis and elevates the levels of early glycolytic intermediates. Although this may be beneficial in the fasted state to conserve systemic glucose, it represents a pathological impairment in diabetes mellitus.

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“…Heart samples were prepared on the basis of our standard targeted proteomics approach 19, 20, 21, 22. Whole heart homogenates were used for the analysis.…”

Section: Methodsmentioning

confidence: 99%

Cardiac Insulin Signaling Regulates Glycolysis Through Phosphofructokinase 2 Content and Activity

Humphries

Matsuzaki

Vadvalkar

et al. 2017

JAHA

View full text Add to dashboard Cite

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“…A good example can be found in cardiomyocytes, which preferentially indeed use long-chain FAs as their energy source and contain large amounts of mitochondria [13]. The large majority of these cells is not able to regenerate, but a small population of "hypoxic" cardiomyocytes (those that have stabilized the hypoxia-inducible factor 1 alpha subunit) can contribute to new cardiomyocyte formation for ongoing repair of the adult heart [14,15]. There is a parallel here with the elusive neural stem cell that allows neuronal regeneration [16].…”

Section: Introductionmentioning

confidence: 99%

Evolution of peroxisomes illustrates symbiogenesis

Speijer

2017

BioEssays

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Recently, the group of McBride reported a stunning observation regarding peroxisome biogenesis: newly born peroxisomes are hybrids of mitochondrial and ER-derived pre-peroxisomes. What was stunning? Studies performed with the yeast Saccharomyces cerevisiae had convincingly shown that peroxisomes are ER-derived, without indications for mitochondrial involvement. However, the recent finding using fibroblasts dovetails nicely with a mechanism inferred to be driving the eukaryotic invention of peroxisomes: reduction of mitochondrial reactive oxygen species (ROS) generation associated with fatty acid (FA) oxidation. This not only explains the mitochondrial involvement, but also its apparent absence in yeast. The latest results allow a reconstruction of the evolution of the yeast's highly derived metabolism and its limitations as a model organism in this instance. As I review here, peroxisomes are eukaryotic inventions reflecting mutual host endosymbiont adaptations: this is predicted by symbiogenetic theory, which states that the defining eukaryotic characteristics evolved as a result of mutual adaptations of two merging prokaryotes.See also the video abstract here: https://youtu.be/ HtyKhQ3DSxg

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“…Perhaps one of the most promising developments in the field of the regenerative cardiology is the emerging notion of using pre-existing cardiomyocytes as the source for cardiomyocyte replacement to maintain normal myocardial homeostasis as well as after myocardial injury [77][78][79][80]. The stimulation of proliferation of pre-existing cardiomyocytes could provide new avenues for future therapeutic strategies to regenerate the heart.…”

Section: Discussionmentioning

confidence: 99%

Concise Review: Mending a Broken Heart: The Evolution of Biological Therapeutics

2017

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Heart failure (HF), a common sequela of cardiovascular diseases, remains a staggering clinical problem, associated with high rates of morbidity and mortality worldwide. Advances in pharmacological, interventional, and operative management have improved patient care, but these interventions are insufficient to halt the progression of HF, particularly the end-stage irreversible loss of functional cardiomyocytes. Innovative therapies that could prevent HF progression and improve the function of the failing heart are urgently needed. Following successful preclinical studies, two main strategies have emerged as potential solutions: cardiac gene therapy and cardiac regeneration through stem and precursor cell transplantation. Many potential gene-and cell-based therapies have entered into clinical studies, intending to ameliorate cardiac dysfunction in patients with advanced HF. In this review, we focus on the recent advances in cell-and gene-based therapies in the context of cardiovascular disease, emphasizing the most advanced therapies. The principles and mechanisms of action of gene and cell therapies for HF are discussed along with the limitations of current approaches. Finally, we highlight the emerging technologies that hold promise to revolutionize the biological therapies for cardiovascular diseases. STEM CELLS 2017;35:1131-1140 SIGNIFICANCE STATEMENTInnovative therapies that could treat heart failure and improve the function of failing hearts are urgently needed. Following successful preclinical studies, two main strategies have emerged as potential solutions: cardiac gene therapy and cardiac regeneration through stem and precursor cell transplantation. Many gene-and cell-based therapies have entered into clinical studies, intending to ameliorate cardiac dysfunction in patients with advanced HF. In this review, we focus on the recent advances in cell-and gene-based therapies in the context of cardiovascular disease, emphasizing the most advanced therapies that have entered the clinical arena.

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Hypoxia induces heart regeneration in adult mice

Cited by 545 publications

References 27 publications

Cardiac Insulin Signaling Regulates Glycolysis Through Phosphofructokinase 2 Content and Activity

Cardiac Insulin Signaling Regulates Glycolysis Through Phosphofructokinase 2 Content and Activity

Evolution of peroxisomes illustrates symbiogenesis

Concise Review: Mending a Broken Heart: The Evolution of Biological Therapeutics

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