Cytochrome c Oxidase Activity Is a Metabolic Checkpoint that Regulates Cell Fate Decisions During T Cell Activation and Differentiation

Тарасенко, Т. Н.; Pacheco, Susan E.; Koenig, Mary Kay; Gómez-Rodríguez, Julio; Kapnick, Senta M.; Díaz, Francisca; Zerfas, Patricia M.; Barca, Emanuele; Sudderth, Jessica; DeBerardinis, Ralph J.; Covián, Raúl; Balaban, Robert S.; DiMauro, Salvatore; McGuire, Peter J.

doi:10.1016/j.cmet.2017.05.007

Cited by 127 publications

(130 citation statements)

References 58 publications

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“…The proteins are transferred to the mitochondria and modify the permeability of mitochondrial outer membranes, making cytochrome c released into cytoplasm and caspases cleaved and activated [18,35]. Ultimately, cascade reaction caused the mitochondrial membrane potential to be lost and downstream events of apoptosis to occur [36]. We observed that exposure to ZA-loaded Mg alloys resulted in the up-regulation of the pro-apoptotic protein Bax and the down-regulation of the anti-apoptotic protein Bcl-2 (Fig.…”

Section: Discussionmentioning

confidence: 99%

Molecular and cellular mechanisms for zoledronic acid-loaded magnesium-strontium alloys to inhibit giant cell tumors of bone

Wang

Zhu

et al. 2018

Acta Biomaterialia

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In clinics, giant cell tumors of bone (GCTB) are removed by surgery. However, the resultant defects in bone still contain aggressive and metastatic GCTB cells that can recruit osteoclasts to damage bone, leading to new GCTB tumor growth and bone damage after tumor surgery. Hence, it is of high demand in developing a material that can not only fill the bone defects as an implant but also inhibit GCTB in the defect area as a therapeutic agent. More importantly, the molecular and cellular mechanism by which such a material inhibits GCTB growth has never been explored. To solve these two problems, we prepared a new biomaterial, the Mg-Sr alloys that were first coated with calcium phosphate and then loaded with a tumor-inhibiting molecule (Zoledronic acid, ZA). Then, by using a variety of molecular and cellular biological assays, we studied how the ZA-loaded alloys induced the death of GCTB cells (derived from patients) and inhibited their growth at the molecular and cellular level. At the cellular level, our results showed that ZA-loaded Mg-Sr alloys not only induced apoptosis and oxidative stress of GCTB cells, and suppressed their induced pre-osteoclast recruitment, but also inhibited their migration. At the molecular level, our data showed that ZA released from the ZA-loaded Mg-Sr alloys could significantly activate the mitochondrial pathway and inhibit the NF-κB pathway in the GCTB cells. Both mechanisms collectively induced GCTB cell death and inhibited GCTB cell growth. This work showed how a biomaterial inhibit tumor growth at the molecular and cellular level, increasing our understanding in the fundamental principle of materials-induced cancer therapy. This work will be interesting to readers in the fields of metallic materials, inorganic materials, biomaterials and cancer therapy.

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Section: Discussionmentioning

confidence: 99%

Molecular and cellular mechanisms for zoledronic acid-loaded magnesium-strontium alloys to inhibit giant cell tumors of bone

Wang

Zhu

et al. 2018

Acta Biomaterialia

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“…Indeed, mitochondrial oxidation plays an important role in T cell activation, as evidenced by the deleterious effects that inhibiting mitochondrial function has on T eff differentiation. [39][40][41] Although inherently inefficient to produce ATP, aerobic glycolysis is required for T cells to engage in productive growth and cytokine production. Part of the pyruvate and glycolytic intermediaries are shuttled toward the synthesis of biomolecules, and the reduction of pyruvate to lactate allows the regeneration of oxidized NAD + , indispensable to continue with the glycolytic process.…”

Section: Upregulation Of Aerobic Glycolysis Upon T Cell Activationmentioning

confidence: 99%

Fatty acid metabolism in CD8⁺ T cell memory: Challenging current concepts

Raud

McGuire

Jones

et al. 2018

Immunological Reviews

104

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Fatty acid metabolism in CD8+ T cell memory CD8+ T cells are key members of the adaptive immune response against infections and cancer. As we discuss in this review, these cells can present diverse metabolic requirements, which have been intensely studied during the past few years. Our current understanding suggests that aerobic glycolysis is a hallmark of activated CD8+ T cells, while naïve and memory (Tmem) cells often rely on oxidative phosphorylation, and thus mitochondrial metabolism is a crucial determinant of CD8+ Tmem cell development. Moreover, it has been proposed that CD8+ Tmem cells have a specific requirement for the oxidation of long-chain fatty acids (LC-FAO), a process modulated in lymphocytes by the enzyme CPT1A. However, this notion relies heavily on the metabolic analysis of in vitro cultures and on chemical inhibition of CPT1A. Therefore, we introduce more recent studies using genetic models to demonstrate that CPT1A-mediated LC-FAO is dispensable for the development of CD8+ T cell memory and protective immunity, and question the use of chemical inhibitors to target this enzyme. We discuss insights obtained from those and other studies analysing the metabolic characteristics of CD8+ Tmem cells, and emphasise how T cells exhibit flexibility in their choice of metabolic fuel.

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“…Indeed, fueling mitochondrial ROS production is a prerequisite for antigen‐specific T‐cell expansion and mitochondria contribute to T‐cell activation as well as to the maintenance of memory and Treg cell subsets . Moreover, distinct T‐cell subsets exhibit different requirements for mitochondrial activity; CD8+ T cells are significantly more sensitive than CD4+ lymphocytes to complex IV dysfunction (regulated by cytochrome c oxidase) with increased mitochondrial mass in CD8 memory cells resulting in a bioenergetic advantage for rapid recall while Tregs are more resistant than T effector (Teff) subsets to mitochondrial failure . Mitochondrial function is linked to its morphology and mitochondrial fusion–fission dynamics have been revealed to regulate immune function; mitofusin‐mediated fusion is required for lymphocyte differentiation of hematopoietic stem cells while memory/effector CD8 T cell generation is balanced by fusion–fission, respectively .…”

Section: Interplay Between Nutrients and Downstream Effectors In T‐cementioning

confidence: 99%

Metabolic orchestration of T lineage differentiation and function

Yong

Moussa²,

Cretenet³

et al. 2017

FEBS Letters

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T cells are stimulated by the engagement of antigen, cytokine, pathogen, and hormone receptors. While research performed over many years has focused on deciphering the molecular components of these pathways, recent data underscore the importance of the metabolic environment in conditioning responses to receptor engagement. The ability of T cells to undergo a massive proliferation and cytokine secretion in response to receptor signals requires alterations to their bioenergetic homeostasis, allowing them to meet new energetic and biosynthetic demands. The metabolic reprogramming of activated T cells is regulated not only by changes in intracellular nutrient uptake and utilization but also by nutrient and oxygen concentrations in the extracellular environment. Notably, the extracellular environment can be profoundly altered by pathological conditions such as infections and tumors, thereby perturbing the metabolism and function of antigen-specific T lymphocytes. This review highlights the interplay between diverse metabolic networks and the transcriptional/epigenetic states that condition T-cell differentiation, comparing the metabolic features of T lymphocytes with other immune cells. We further address recent discoveries in the metabolic pathways that govern T-cell function in physiological and pathological conditions.

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Cytochrome c Oxidase Activity Is a Metabolic Checkpoint that Regulates Cell Fate Decisions During T Cell Activation and Differentiation

Cited by 127 publications

References 58 publications

Molecular and cellular mechanisms for zoledronic acid-loaded magnesium-strontium alloys to inhibit giant cell tumors of bone

Molecular and cellular mechanisms for zoledronic acid-loaded magnesium-strontium alloys to inhibit giant cell tumors of bone

Fatty acid metabolism in CD8⁺ T cell memory: Challenging current concepts

Metabolic orchestration of T lineage differentiation and function

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Cytochrome c Oxidase Activity Is a Metabolic Checkpoint that Regulates Cell Fate Decisions During T Cell Activation and Differentiation

Cited by 127 publications

References 58 publications

Molecular and cellular mechanisms for zoledronic acid-loaded magnesium-strontium alloys to inhibit giant cell tumors of bone

Molecular and cellular mechanisms for zoledronic acid-loaded magnesium-strontium alloys to inhibit giant cell tumors of bone

Fatty acid metabolism in CD8+ T cell memory: Challenging current concepts

Metabolic orchestration of T lineage differentiation and function

Contact Info

Product

Resources

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Fatty acid metabolism in CD8⁺ T cell memory: Challenging current concepts