André Terzic scite author profile

SUMMARY The bioenergetics of somatic dedifferentiation into induced pluripotent stem cells remains largely unknown. Here, stemness factor mediated nuclear reprogramming reverted mitochondrial networks into cristae-poor structures. Metabolomic footprinting and fingerprinting distinguished derived pluripotent progeny from parental fibroblasts according to elevated glucose utilization and production of glycolytic end products. Temporal sampling demonstrated glycolytic gene potentiation prior to induction of pluripotent markers. Functional metamorphosis of somatic oxidative phosphorylation into acquired pluripotent glycolytic metabolism conformed to an embryonic-like archetype. Stimulation of glycolysis promoted, while blockade of glycolytic enzyme activity blunted, reprogramming efficiency. Metaboproteomics resolved upregulated glycolytic enzymes and downregulated electron transport chain complex I subunits underlying cell fate determination. Thus, the energetic infrastructure of somatic cells transitions into a required glycolytic metabotype to fuel induction of pluripotency.

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Metabolic Plasticity in Stem Cell Homeostasis and Differentiation

Folmes

et al. 2012

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Plasticity in energy metabolism allows stem cells to match the divergent demands of self-renewal and lineage specification. Beyond a role in energetic support, new evidence implicates nutrient-responsive metabolites as mediators of crosstalk between metabolic flux, cellular signaling, and epigenetic regulation of cell fate. Stem cell metabolism also offers a potential target for controlling tissue homeostasis and regeneration in aging and disease. In this Perspective, we cover recent progress establishing an emerging relationship between stem cell metabolism and cell fate control.

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Mitochondrial oxidative metabolism is required for the cardiac differentiation of stem cells

Chung¹,

Dzeja²,

Faustino³

et al. 2007

Nat Rev Cardiol

465

482

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SUMMARYCardiogenesis within embryos or associated with heart repair requires stem cell differentiation into energetically competent, contracting cardiomyocytes. While it is widely accepted that the coordination of genetic circuits with developmental bioenergetics is critical to phenotype specification, the metabolic mechanisms that drive cardiac transformation are largely unknown. Here, we aim to define the energetic requirements for and the metabolic microenvironment needed to support the cardiac differentiation of embryonic stem cells. We demonstrate that anaerobic glycolytic metabolism, while sufficient for embryonic stem cell homeostasis, must be transformed into the more efficient mitochondrial oxidative metabolism to secure cardiac specification and excitation-contraction coupling. This energetic switch was programmed by rearrangement of the metabolic transcriptome that encodes components of glycolysis, fatty acid oxidation, the Krebs cycle, and the electron transport chain. Modifying the copy number of regulators of mitochondrial fusion and fission resulted in mitochondrial maturation and network expansion, which in turn provided an energetic continuum to supply nascent sarcomeres. Disrupting respiratory chain function prevented mitochondrial organization and compromised the energetic infrastructure, causing deficient sarcomerogenesis and contractile malfunction. Thus, establishment of the mitochondrial system and engagement of oxidative metabolism are prerequisites for the differentiation of stem cells into a functional cardiac phenotype. Mitochondria-dependent energetic circuits are thus critical regulators of de novo cardiogenesis and targets for heart regeneration.

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Kir6.2 is required for adaptation to stress

Zingman

Hodgson

Bast

et al. 2002

Proc. Natl. Acad. Sci. U.S.A.

285

375

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Reaction to stress requires feedback adaptation of cellular functions to secure a response without distress, but the molecular order of this process is only partially understood. Here, we report a previously unrecognized regulatory element in the general adaptation syndrome. Kir6.2, the ion-conducting subunit of the metabolically responsive ATP-sensitive potassium (KATP) channel, was mandatory for optimal adaptation capacity under stress. Genetic deletion of Kir6.2 disrupted KATP channel-dependent adjustment of membrane excitability and calcium handling, compromising the enhancement of cardiac performance driven by sympathetic stimulation, a key mediator of the adaptation response. In the absence of Kir6.2, vigorous sympathetic challenge caused arrhythmia and sudden death, preventable by calcium-channel blockade. Thus, this vital function identifies a physiological role for KATP channels in the heart. I on channels control the electrical potential across the cell membrane of all living organisms. The profile of channel expression within the cell is defined by evolution through natural selection (1, 2). Developed as channel͞enzyme multimers, K ATP channels combine properties of two different classes of protein to adjust rapidly and precisely membrane excitability according to the metabolic state of the cell (3-7). Identified in metabolically active tissues of a broad range of species, K ATP channels were discovered originally in heart muscle where they are expressed in high density (8, 9). Functional cardiac K ATP channels can be formed only through physical association of the pore-forming Kir6.2 subunit with the regulatory sulfonylurea receptor SUR2A (10-12). In this complex, which harbors an intrinsic ATPase activity, nucleotide interaction at SUR2A gates potassium permeation through Kir6.2, a property believed to be responsible for the fine metabolic modulation of membrane potential-dependent cellular functions (7,(13)(14)(15)(16).The physiological role of K ATP channels as metabolic sensors has been understood best in the regulation of hormone secretion in pancreatic ␤-cells and more recently in the hypothalamus (17-21). In the heart, definition of the function of this protein complex thus far has been limited to acute protection against ischemic events (22). In fact, under ischemia, the opening of as few as 1% of K ATP channels is sufficient to produce significant shortening of the cardiac action potential (23), manifested globally by ST-segment elevation on the electrocardiogram (24). Yet, beyond the impact in pathophysiology, a physiological role for the cardiac K ATP channel that supports its maintenance in hearts of many species is lacking (25).The general adaptation syndrome is a ubiquitous reaction vital for self-preservation under conditions of stress such as exertion or fear (26-28). Mediated by a catecholamine surge, this syndrome generates an alteration of physiologic and biochemical functions to sustain a superior level of bodily performance and allows confrontation or escape in response to threat...

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André Terzic

Somatic Oxidative Bioenergetics Transitions into Pluripotency-Dependent Glycolysis to Facilitate Nuclear Reprogramming

Metabolic Plasticity in Stem Cell Homeostasis and Differentiation

Mitochondrial oxidative metabolism is required for the cardiac differentiation of stem cells

Kir6.2 is required for adaptation to stress

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