A mitochondrial redox oxygen sensor in the pulmonary vasculature and ductus arteriosus

Dunham‐Snary, Kimberly J.; Hong, Zhigang; Xiong, Ping Yu; Paggio, Joseph C Del; Herr, Julia E.; Johri, Amer M.; Archer, Stephen L.

doi:10.1007/s00424-015-1736-y

Cited by 32 publications

(27 citation statements)

References 104 publications

(142 reference statements)

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“…Hence, Kv channel sensitivity to ROS would be similar in PASMC and SASMC but opposite to that in DA, whereas mitochondria in PASMC and DA decrease ROS in response to hypoxia whereas those in SASMC increase ROS generation. This complex set of proposed mechanisms has been the topic of previous reviews 33, 35–38 , and is summarized in Table 1.…”

Section: Mitochondrial Ros As Signaling Messengers In Hypoxiamentioning

confidence: 99%

O 2 sensing, mitochondria and ROS signaling: The fog is lifting

Waypa

Smith

Schumacker

2016

Molecular Aspects of Medicine

152

121

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Mitochondria are responsible for the majority of oxygen consumption in cells, and thus represent a conceptually appealing site for cellular oxygen sensing. Over the past 40 years a number of mechanisms to explain how mitochondria participate in oxygen sensing have been proposed. However, no consensus has been reached regarding how mitochondria could regulate transcriptional and post-translational responses to hypoxia. Nevertheless, a growing body of data continues to implicate a role for increased reactive oxygen species (ROS) signals from the electron transport chain (ETC) in triggering responses to hypoxia in diverse cell types. The present article reviews our progress understanding this field and considers recent advances that provide new insight, helping to lift the fog from this complex topic.

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Section: Mitochondrial Ros As Signaling Messengers In Hypoxiamentioning

confidence: 99%

O 2 sensing, mitochondria and ROS signaling: The fog is lifting

Waypa

Smith

Schumacker

2016

Molecular Aspects of Medicine

152

121

View full text Add to dashboard Cite

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“…4b). However, this theory is not without its critics and remains a source of ongoing debate (Ward 2006;Weir and Archer 2006), considered by some as controversial if not indeed counterintuitive (↓O 2 → ↓ electron flux/uncoupled leakage) with evidence supporting a more direct link between molecular O 2 and PHD inhibition/HIF activation (Dunham-Snary et al 2016).…”

Section: •−mentioning

confidence: 99%

RETRACTED ARTICLE: The quantum physiology of oxygen; from electrons to the evolution of redox signaling in the human brain

Bailey

2018

Bioelectron Med

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Rising atmospheric oxygen (O 2) levels provided a selective pressure for the evolution of O 2-dependent microorganisms that began with the autotrophic eukaryotes. Since these primordial times, the respiring mammalian cell has become entirely dependent on the constancy of electron flow with molecular O 2 serving as the terminal electron acceptor in mitochondrial oxidative phosphorylation. Indeed, the ability to "sense" O 2 and maintain homeostasis is considered one of the most important roles of the central nervous system (CNS) and likely represented a major driving force in the evolution of the human brain. Today, modern humans have evolved with an oversized brain committed to a continually active state and as a consequence, paradoxically vulnerable to failure if the O 2 supply is interrupted. However, our preoccupation with O 2 , the elixir of life, obscures the fact that it is a gas with a Janus Face, capable of sustaining life in physiologically controlled amounts yet paradoxically deadly to the CNS when in excess. A closer look at its quantum structure reveals precisely why; the triplet ground state diatomic O 2 molecule is paramagnetic and exists in air as a free radical, constrained from reacting aggressively with the brain's organic molecules due to its "spin restriction", a thermodynamic quirk of evolutionary fate. By further exploring O 2 's free radical "quantum quirkiness" including emergent quantum physiological phenomena, our understanding of precisely how the human brain senses O 2 deprivation (hypoxia) and the elaborate redox-signaling defense mechanisms that defend O 2 homeostasis has the potential to offer unique insights into the pathophysiology and treatment of human brain disease.

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“…Our studies demonstrate that the reduction in CES1 expression and activity increases PMVEC apoptosis alone and in response to METH, but several questions remain concerning the mechanism behind METH-induced ROS generation, initiation of ER stress, and possible impairment of mitochondrial bioenergetics, a well-established feature of other forms of PAH (14,37,46). It is worth pointing out that mitochondrial toxicity is also a consequence of METH exposure and could be linked to the autophagy response, as these pathways can also interact with the mitochondria to trigger release of cytochrome c and other proapoptotic factors (52,59).…”

Section: L261mentioning

confidence: 76%

Reduced carboxylesterase 1 is associated with endothelial injury in methamphetamine-induced pulmonary arterial hypertension

Orcholski

Khurshudyan

Shamskhou

et al. 2017

American Journal of Physiology-Lung Cellular and Molecular Phys

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Pulmonary arterial hypertension is a complication of methamphetamine use (METH-PAH), but the pathogenic mechanisms are unknown. Given that cytochrome P450 2D6 (CYP2D6) and carboxylesterase 1 (CES1) are involved in metabolism of METH and other amphetamine-like compounds, we postulated that loss of function variants could contribute to METH-PAH. Although no difference in CYP2D6 expression was seen by lung immunofluorescence, CES1 expression was significantly reduced in endothelium of METH-PAH microvessels. Mass spectrometry analysis showed that healthy pulmonary microvascular endothelial cells (PMVECs) have the capacity to both internalize and metabolize METH. Furthermore, whole exome sequencing data from 18 METH-PAH patients revealed that 94.4% of METH-PAH patients were heterozygous carriers of a single nucleotide variant (SNV; rs115629050) predicted to reduce CES1 activity. PMVECs transfected with this CES1 variant demonstrated significantly higher rates of METH-induced apoptosis. METH exposure results in increased formation of reactive oxygen species (ROS) and a compensatory autophagy response. Compared with healthy cells, CES1-deficient PMVECs lack a robust autophagy response despite higher ROS, which correlates with increased apoptosis. We propose that reduced CES1 expression/activity could promote development of METH-PAH by increasing PMVEC apoptosis and small vessel loss.

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A mitochondrial redox oxygen sensor in the pulmonary vasculature and ductus arteriosus

Cited by 32 publications

References 104 publications

O 2 sensing, mitochondria and ROS signaling: The fog is lifting

O 2 sensing, mitochondria and ROS signaling: The fog is lifting

RETRACTED ARTICLE: The quantum physiology of oxygen; from electrons to the evolution of redox signaling in the human brain

Reduced carboxylesterase 1 is associated with endothelial injury in methamphetamine-induced pulmonary arterial hypertension

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