IEX-1 targets mitochondrial F1Fo-ATPase inhibitor for degradation

Shen, Li; Liu, Zhi; Hu, Wentao; Wu, Minxian

doi:10.1038/cdd.2008.184

Cited by 62 publications

(75 citation statements)

References 39 publications

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“…1C), the protein will inhibit both the synthetic and hydrolytic activities. In agreement with our proposal, recent findings indicate that deletion of IEX-1, a stress-inducible gene that apparently targets IF1 for degradation, results in the inhibition of the ATP synthase activity in vivo (29).…”

Section: Discussionsupporting

confidence: 80%

Up-regulation of the ATPase Inhibitory Factor 1 (IF1) of the Mitochondrial H+-ATP Synthase in Human Tumors Mediates the Metabolic Shift of Cancer Cells to a Warburg Phenotype

Sánchez‐Cenizo

Formentini

Aldea

et al. 2010

Journal of Biological Chemistry

189

228

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The H؉ -ATP synthase is a reversible engine of mitochondria that synthesizes or hydrolyzes ATP upon changes in cell physiology. ATP synthase dysfunction is involved in the onset and progression of diverse human pathologies. During ischemia, the ATP hydrolytic activity of the enzyme is inhibited by the ATPase inhibitory factor 1 (IF1 In oxidative phosphorylation, ATP is synthesized by the mitochondrial ATP synthase, a H ϩ -driven rotatory engine of the inner membrane that utilizes as driving force for ATP synthesis the H ϩ electrochemical gradient generated by the respiratory chain (1-4). The cellular expression level of ␤-F1-ATPase, 2 which is the catalytic subunit of the H ϩ -ATP synthase, is diminished in diverse human pathologies (5), which include cancer (6 -9), affording a relevant marker of disease progression (6, 7, 10 -12) and of the response to chemotherapy (7,(13)(14)(15). Moreover, the down-regulation of ␤-F1-ATPase in lung carcinomas (12) and colon cancer cells (15) also provides a mechanistic explanation to the increased glucose avidity of carcinomas, i.e. to the enhanced aerobic glycolysis of cancer cells (16,17). Interestingly, the quantitative determination of ␤-F1-ATPase relative to the content of glyceraldehyde-3-phosphate dehydrogenase in human tumors has revealed that cancer abolishes the tissue-specific differences in the cellular complement of the bioenergetic ␤-F1-ATPase protein (18).It is well established that when mitochondrial respiration is impaired, the H ϩ -ATP synthase can function in reverse acting as an ATP hydrolase for maintaining the proton motive force (1,19). This process is regulated by an inhibitor peptide called ATPase inhibitory factor 1 or IF1 (19 -21), a highly conserved nuclearly encoded protein. When matrix pH drops, IF1 becomes activated and binds ␤-F1-ATPase, blocking ATP hydrolysis and preventing a useless waste of energy (20). The substitution of histidine 49 in IF1 by a lysine residue renders a mutant form (H49K) that inhibits the ATP hydrolase activity in a pH-insensitive way (22). The structure and in vitro mechanism of action of IF1 has been studied in detail, and its role as an inhibitor of the hydrolase activity of the H ϩ -ATP synthase is well documented (19,20,23). However, the information on IF1 expression in human tissues and its putative contribution to the development of human pathology are unknown. In this study, we demonstrate that IF1 is overexpressed in human carcinomas. Moreover, we document that IF1 plays a regulatory role in controlling cellular energetic metabolism, strongly supporting its participation as an additional molecular switch used by cancer cells to trigger the induction of aerobic glycolysis, i.e. their Warburg phenotype. 2 The abbreviations used are: ␤-F1-ATPase, ␤ catalytic subunit of the H ϩ -ATP synthase; IF1, ATPase inhibitory factor 1; FCCP, carbonyl cyanide-p-trifluoromethoxyphenylhydrazone; siRNA, small interfering RNA; NRK, normal rat kidney. EXPERIMENTAL PROCEDURES

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Section: Discussionsupporting

confidence: 80%

Up-regulation of the ATPase Inhibitory Factor 1 (IF1) of the Mitochondrial H+-ATP Synthase in Human Tumors Mediates the Metabolic Shift of Cancer Cells to a Warburg Phenotype

Sánchez‐Cenizo

Formentini

Aldea

et al. 2010

Journal of Biological Chemistry

189

228

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“…15 Our previous investigation showed that mice lacking immediate early responsive gene X-1 (IEX-1) were more susceptible to secondary brain injury than their wild-type littermates, because the null mutation of IEX-1 adversely affected mitochondrial functions and therefore diminished ATP formation in the injured brain. 16,17 Interestingly, noninvasive LLL illumination robustly enhanced ATP generation in injured brains of IEX-1 knockout mice. The enhancement was correlated positively and proportionally with LLL-mediated protection against secondary brain injury in the mice, suggesting a key role for mitochondria in both the pathogenesis of secondary brain injury and the effectiveness of LLL.…”

Section: Traumatic Brain Injury (Tbi)mentioning

confidence: 99%

Low-Level Light in Combination with Metabolic Modulators for Effective Therapy of Injured Brain

Dong

Zhang

Hamblin

et al. 2015

J Cereb Blood Flow Metab

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Vascular damage occurs frequently at the injured brain causing hypoxia and is associated with poor outcomes in the clinics. We found high levels of glycolysis, reduced adenosine triphosphate generation, and increased formation of reactive oxygen species and apoptosis in neurons under hypoxia. Strikingly, these adverse events were reversed significantly by noninvasive exposure of injured brain to low-level light (LLL). Low-level light illumination sustained the mitochondrial membrane potential, constrained cytochrome c leakage in hypoxic cells, and protected them from apoptosis, underscoring a unique property of LLL. The effect of LLL was further bolstered by combination with metabolic substrates such as pyruvate or lactate both in vivo and in vitro. The combinational treatment retained memory and learning activities of injured mice to a normal level, whereas other treatment displayed partial or severe deficiency in these cognitive functions. In accordance with well-protected learning and memory function, the hippocampal region primarily responsible for learning and memory was completely protected by combination treatment, in marked contrast to the severe loss of hippocampal tissue because of secondary damage in control mice. These data clearly suggest that energy metabolic modulators can additively or synergistically enhance the therapeutic effect of LLL in energyproducing insufficient tissue-like injured brain.

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“…The immediate early responsive gene X-1 (IEX-1) has a pivotal role in regulation of mitochondrial F 1 F 0 -ATPase activity, in protection against apoptosis, and in resolution of inflammation. [13][14][15] Null mutation of IEX-1 enhanced apoptosis, 16 reduced ATP synthase activity, 17 and prolonged inflammatory responses in a tissue-dependent manner in mice. 15,18 Furthermore, IEX-1 is upregulated by NF-kB and in turn inhibits NF-kB activation as a negative feedback mechanism contributing to inflammation resolution.…”

Section: Traumatic Brain Injury (Tbi) Represents a Serious Public Healthmentioning

confidence: 99%

Low-Level Laser Therapy Effectively Prevents Secondary Brain Injury Induced by Immediate Early Responsive Gene X-1 Deficiency

Zhang

Zhou

Hamblin

et al. 2014

J Cereb Blood Flow Metab

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A mild insult to the brain can sometimes trigger secondary brain injury, causing severe postconcussion syndrome, but the underlying mechanism is ill understood. We show here that secondary brain injury occurs consistently in mice lacking immediate early responsive gene X-1 (IEX-1), after a gentle impact to the head, which closely simulates mild traumatic brain injury in humans. The pathologic lesion was characterized by extensive cell death, widespread leukocyte infiltrates, and severe tissue loss. On the contrary, a similar insult did not induce any secondary injury in wild-type mice. Strikingly, noninvasive exposure of the injured head to a low-level laser at 4 hours after injury almost completely prevented the secondary brain injury in IEX-1 knockout mice. The low-level laser therapy (LLLT) suppressed proinflammatory cytokine expression like interleukin (IL)-1b and IL-6 but upregulated TNF-a. Moreover, although lack of IEX-1 compromised ATP synthesis, LLLT elevated its production in injured brain. The protective effect of LLLT may be ascribed to enhanced ATP production and selective modulation of proinflammatory mediators. This new closed head injury model provides an excellent tool to investigate the pathogenesis of secondary brain injury as well as the mechanism underlying the beneficial effect of LLLT.

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IEX-1 targets mitochondrial F1Fo-ATPase inhibitor for degradation

Cited by 62 publications

References 39 publications

Up-regulation of the ATPase Inhibitory Factor 1 (IF1) of the Mitochondrial H+-ATP Synthase in Human Tumors Mediates the Metabolic Shift of Cancer Cells to a Warburg Phenotype

Up-regulation of the ATPase Inhibitory Factor 1 (IF1) of the Mitochondrial H+-ATP Synthase in Human Tumors Mediates the Metabolic Shift of Cancer Cells to a Warburg Phenotype

Low-Level Light in Combination with Metabolic Modulators for Effective Therapy of Injured Brain

Low-Level Laser Therapy Effectively Prevents Secondary Brain Injury Induced by Immediate Early Responsive Gene X-1 Deficiency

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