NAD+/NADH and/or CoQ/CoQH2 ratios from plasma membrane electron transport may determine ceramide and sphingosine‐1‐phosphate levels accompanying G1 arrest and apoptosis

Luca, Thomas De; Morré, Dorothy M.; Zhao, Huijuan; Morré, D. James

doi:10.1002/biof.5520250106

Cited by 52 publications

(34 citation statements)

References 55 publications

(61 reference statements)

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“…3,26 DeLuca et al 13 proposed that inhibition of PMET via tNOX results in increased levels of intracellular NADH and membrane ubiquinol, inhibiting sphingosine kinase and increasing membrane ceramide levels, which induce G1 arrest and apoptosis. In contrast, activity of constitutively-expressed cell surface NADH-oxidase, CNOX, present on both cancer and non-cancer cells, was said to be unaffected by phenoxodiol; thus, phenoxodiol has been heralded as a pan-cancer drug.…”

Section: Discussionmentioning

confidence: 99%

“…1,2 Phenoxodiol has been referred to as a pan-cancer drug, 3 causing apoptosis in cancer cell lines and murine cancer models via both intrinsic and extrinsic pathways. [4][5][6][7][8][9][10][11][12][13][14] Plasma membrane electron transport (PMET) has been shown to be a target of phenoxodiol in several studies with cancer cell lines. 3,13,15 PMET consists of an outer membrane (surface) NADH-oxidoreductase, redox-recycling plasma membrane ubiquinone and an inner membrane NADH-oxidoreductase.…”

Section: Introductionmentioning

confidence: 99%

“…[4][5][6][7][8][9][10][11][12][13][14] Plasma membrane electron transport (PMET) has been shown to be a target of phenoxodiol in several studies with cancer cell lines. 3,13,15 PMET consists of an outer membrane (surface) NADH-oxidoreductase, redox-recycling plasma membrane ubiquinone and an inner membrane NADH-oxidoreductase. 16 PMET plays a vital role in maintaining both plasma membrane and intracellular redox balances to support continued cell survival, function and growth of fast proliferating cells.…”

Section: Introductionmentioning

confidence: 99%

“…16 PMET plays a vital role in maintaining both plasma membrane and intracellular redox balances to support continued cell survival, function and growth of fast proliferating cells. 13,17,18 Most cancer cells actively increase glucose uptake to meet increased energy demands; this is associated with increased NADH recycling to maintain intracellular NADH/NAD + ratios. Cells that generate most of their energy through oxidative phosphorylation recycle NADH mainly through mitochondrial electron transport.…”

Section: Introductionmentioning

confidence: 99%

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The anti-cancer drug, phenoxodiol, kills primary myeloid and lymphoid leukemic blasts and rapidly proliferating T cells

Herst¹,

Davis²,

Neeson³

et al. 2009

Haematologica

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The online version of this article contains a supplementary appendix. BackgroundThe redox-active isoflavene anti-cancer drug, phenoxodiol, has previously been shown to inhibit plasma membrane electron transport and cell proliferation and promote apoptosis in a range of cancer cell lines and in anti-CD3/anti-CD28-activated murine splenocytes but not in non-transformed WI-38 cells and human umbilical vein endothelial cells. Design and MethodsWe determined the effects of phenoxodiol on plasma membrane electron transport, MTT responses and viability of activated and resting human T cells. In addition, we evaluated the effect of phenoxodiol on the viability of leukemic cell lines and primary myeloid and lymphoid leukemic blasts. ResultsWe demonstrated that phenoxodiol inhibited plasma membrane electron transport and cell proliferation (IC50 46 µM and 5.4 µM, respectively) and promoted apoptosis of rapidly proliferating human T cells but did not affect resting T cells. Phenoxodiol also induced apoptosis in T cells stimulated in HLA-mismatched allogeneic mixed lymphocyte reactions. Conversely, non-proliferating T cells in the mixed lymphocyte reaction remained viable and could be restimulated in a third party mixed lymphocyte reaction, in the absence of phenoxodiol. In addition, we demonstrated that leukemic blasts from patients with primary acute myeloid leukemia (n=22) and acute lymphocytic leukemia (n=8) were sensitive to phenoxodiol. The lymphocytic leukemic blasts were more sensitive than the myeloid leukemic blasts to 10 µM phenoxodiol exposure for 24h (viability of 23±4% and 64±5%, respectively, p=0.0002). ConclusionsThe ability of phenoxodiol to kill rapidly proliferating lymphocytes makes this drug a promising candidate for the treatment of pathologically-activated lymphocytes such as those in acute lymphoid leukemia, or diseases driven by T-cell proliferation such as autoimmune diseases and graft-versus-host disease.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The anti-cancer drug, phenoxodiol, kills primary myeloid and lymphoid leukemic blasts and rapidly proliferating T cells

Herst¹,

Davis²,

Neeson³

et al. 2009

Haematologica

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“…There is a specific form of cell death, eryptosis, in nonnucleate cells such as red blood cells that is apoptosis-like in morphology (Lang et al, 2006). Eryptosis requires caspases as well as Ca 2+ -dependent channels and formation of ceramide (Lang et al, 2006), all of which can be affected by the status of glucose metabolism and levels of ATP (De Luca et al, 2005;Henquin, 2000). Therefore, eryptosis is also an energy-dependent form of cell death.…”

Section: Introductionmentioning

confidence: 99%

Chapter Twenty‐Two Mechanisms and Methods in Glucose Metabolism and Cell Death

Zhao

Wieman

Jacobs

et al. 2008

Methods in Enzymology

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Glucose metabolism represents a critical physiological program that not only provides energy to support cell proliferation, but also directly modulates signaling pathways of cell death. With the growing recognition of regulation of cell death by glucose metabolism, many techniques that can be applied in the study have been developed. This chapter discusses several protocols that aid in the analysis of glucose metabolism and cell death and the principles in practicing them under different conditions.

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Non‐mitochondrial coenzyme Q

Morré

Morré²

2011

BioFactors

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The key role of coenzyme Q (ubiquinone or Q) is in mitochondrial and prokaryotic energetics. Less well investigated is the basis for its presence in eukaryotic membrane locations other than mitochondria and in plasma where both antioxidant and potentially more targeted roles are indicated. Included in the latter is that of a lipid-soluble electron transfer intermediate that serves as the transmembrane component of plasma membrane and Golgi apparatus electron transport, which regulates cytosolic NAD(+) /NADH ratios and is involved in vectorial membrane displacements and in the regulation of cell growth. Important protective effects on circulating lipoproteins and in the prevention of coronary artery disease ensue not only from the antioxidant role of CoQ(10) but also from its ability to directly block protein oxidation and superoxide generation of the TM-9 family of membrane proteins known as age-related NADH oxidase or arNOX (ENOX3) and their shed forms that appear after age 30 and some of which associate specifically with low-density lipoprotein particles to catalyze protein oxidation and crosslinking.

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NAD⁺/NADH and/or CoQ/CoQH₂ ratios from plasma membrane electron transport may determine ceramide and sphingosine‐1‐phosphate levels accompanying G₁ arrest and apoptosis

Cited by 52 publications

References 55 publications

The anti-cancer drug, phenoxodiol, kills primary myeloid and lymphoid leukemic blasts and rapidly proliferating T cells

The anti-cancer drug, phenoxodiol, kills primary myeloid and lymphoid leukemic blasts and rapidly proliferating T cells

Chapter Twenty‐Two Mechanisms and Methods in Glucose Metabolism and Cell Death

Non‐mitochondrial coenzyme Q

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