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Query: UMLS:C0242706 (
hyperoxia
)
5,219
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Oxygen (O(2)) is a prerequisite for cellular respiration in aerobic organisms but also elicits toxicity. To understand how animals cope with the ambivalent physiological nature of O(2), it is critical to elucidate the molecular mechanisms responsible for O(2) sensing. Here our systematic evaluation of transient receptor potential (TRP) cation channels using reactive disulfides with different redox potentials reveals the capability of
TRPA1
to sense O(2). O(2) sensing is based upon disparate processes: whereas prolyl hydroxylases (PHDs) exert O(2)-dependent inhibition on
TRPA1
activity in normoxia, direct O(2) action overrides the inhibition via the prominent sensitivity of
TRPA1
to cysteine-mediated oxidation in
hyperoxia
. Unexpectedly,
TRPA1
is activated through relief from the same PHD-mediated inhibition in hypoxia. In mice, disruption of the Trpa1 gene abolishes
hyperoxia
- and hypoxia-induced cationic currents in vagal and sensory neurons and thereby impedes enhancement of in vivo vagal discharges induced by
hyperoxia
and hypoxia. The results suggest a new O(2)-sensing mechanism mediated by
TRPA1
.
...
PMID:TRPA1 underlies a sensing mechanism for O2. 2193 15
The transient receptor potential (trp) gene superfamily encodes cation channels that act as multimodal sensors for a wide variety of stimuli from outside and inside the cell. Upon sensing, they transduce electrical and Ca(2+) signals via their cation channel activities. These functional features of TRP channels allow the body to react and adapt to different forms of environmental changes. Indeed, members of one class of TRP channels have emerged as sensors of gaseous messenger molecules that control various cellular processes. Nitric oxide (NO), a vasoactive gaseous molecule, regulates TRP channels directly via cysteine (Cys) S-nitrosylation or indirectly via cyclic GMP (cGMP)/protein kinase G (PKG)-dependent phosphorylation. Recent studies have revealed that changes in the availability of molecular oxygen (O(2)) also control the activation of TRP channels. Anoxia induced by O(2)-glucose deprivation and severe hypoxia (1% O(2)) activates TRPM7 and TRPC6, respectively, whereas
TRPA1
has recently been identified as a novel sensor of
hyperoxia
and mild hypoxia (15% O(2)) in vagal and sensory neurons.
TRPA1
also detects other gaseous molecules such as hydrogen sulfide (H(2)S) and carbon dioxide (CO(2)). In this review, we focus on how signaling by gaseous molecules is sensed and integrated by TRP channels.
...
PMID:TRP channels: sensors and transducers of gasotransmitter signals. 2293 72
The transient receptor potential (trp) gene superfamily encodes TRP proteins that act as multimodal sensor cation channels for a wide variety of stimuli from outside and inside the cell. Upon chemical or physical stimulation of cells, TRP channels transduce electrical and/or Ca(2+) signals via their cation channel activities. These functional features of TRP channels allow the body to react and adapt to different forms of environmental changes. Indeed, members of one class of TRP channels have emerged as sensors of reactive oxygen species (ROS), reactive nitrogen species (RNS), reactive carbonyl species (RCS), and gaseous messenger molecules including molecular oxygen (O2), hydrogen sulfide (H2S), and carbon dioxide (CO2). Hydrogen peroxide (H2O2), an ROS, triggers the production of ADP-ribose, which binds and activates TRPM2. In addition to TRPM2, TRPC5, TRPV1, and
TRPA1
are also activated by H2O2 via modification of cysteine (Cys) free sulfhydryl groups. Nitric oxide (NO), a vasoactive gaseous molecule, regulates TRP channels directly via Cys S-nitrosylation or indirectly via cyclic GMP (cGMP)/protein kinase G (PKG)-dependent phosphorylation. Anoxia induced by O2-glucose deprivation and severe hypoxia activates TRPM7 and TRPC6, respectively, whereas
TRPA1
serves as a sensor of mild hypoxia and
hyperoxia
in vagal and sensory neurons.
TRPA1
also detects other gaseous molecules, such as hydrogen sulfide (H2S) and carbon dioxide (CO2). In this review, we highlight our current knowledge of TRP channels as chemosensors for ROS, RNS, RCS, and gaseous molecules and discuss their functional impacts on physiological and pathological events.
...
PMID:TRPs as chemosensors (ROS, RNS, RCS, gasotransmitters). 2496 69
This review tackles the unresolved issue of the existence of oxygen sensor in the body. The sensor that would respond to changes in tissue oxygen content, possibly along the hypoxia-normoxia-
hyperoxia
spectrum, rather than to a given level of oxygen, and would translate the response into lung ventilation changes, the major adaptive process. Studies on oxygen sensing, for decades, concentrated around the hypoxic ventilatory response generated mostly by carotid body chemoreceptor cells. Despite gaining a substantial insight into the cellular transduction pathways in carotid chemoreceptors, the exact molecular mechanisms of the chemoreflex have never been conclusively verified. The article briefly sums up the older studies and presents novel theories on oxygen, notably, hypoxia sensing. These theories have to do with the role of transient receptor potential cation
TRPA1
channels and brain astrocytes in hypoxia sensing. Although both play a substantial role in shaping the ventilatory response to hypoxia, neither can yet be considered the ultimate sensor of hypoxia. The enigma of oxygen sensing in tissue still remains to be resolved.
...
PMID:Oxygen Sensing Mechanisms: A Physiological Penumbra. 2757 43
Transient Receptor Potential (TRP) proteins form cation channels characterized by a wide variety of activation triggers. Here, we overview a group of TRP channels that respond to reactive redox species to transduce physiological signals, with a focus on
TRPA1
and its role in oxygen physiology. Our systematic evaluation of oxidation sensitivity using cysteine-selective reactive disulphides with different redox potentials reveals that
TRPA1
has the highest sensitivity to oxidants/electrophiles among the TRP channels, which enables it to sense O
2
. Proline hydroxylation by O
2
-dependent hydroxylases also regulates the O
2
-sensing function by inhibiting
TRPA1
in normoxia;
TRPA1
is activated by hypoxia through relief from the inhibition and by
hyperoxia
through cysteine oxidation that overrides the inhibition.
TRPA1
enhances neuronal discharges induced by
hyperoxia
and hypoxia in the vagus to underlie respiratory adaptation to changes in O
2
availability. This importance of
TRPA1
in non-carotid body O
2
sensors can be extended to the universal significance of redox-sensitive TRP channels in O
2
adaptation.
...
PMID:TRP channels in oxygen physiology: distinctive functional properties and roles of TRPA1 in O
2
sensing. 2876 17
Hypoxia sensors are essential for regulating local oxygen (O
2
) homeostasis within the body. This is especially pertinent within the CNS, which is particularly vulnerable to O
2
deprivation due to high energetic demand. Here, we reveal hypoxia-monitoring function exerted by astrocytes through an O
2
-regulated protein trafficking mechanism within the CNS. Strikingly, cultured mouse astrocytes isolated from the parafacial respiratory group (pFRG) and retrotrapezoid nucleus (RTN) region are capable of rapidly responding to moderate hypoxia via the sensor cation channel transient receptor potential (TRP) A1 but, unlike multimodal sensory neurons, are inert to
hyperoxia
and other
TRPA1
activators (carbon dioxide, electrophiles, and oxidants) in normoxia. Mechanistically, O
2
suppresses
TRPA1
channel activity by protein internalization via O
2
-dependent proline hydroxylation and subsequent ubiquitination by an E3 ubiquitin ligase, NEDD4-1 (neural precursor cell-expressed developmentally down-regulated protein 4). Hypoxia inhibits this process and instantly accumulates
TRPA1
proteins at the plasma membrane, inducing
TRPA1
-mediated Ca
2+
influx that triggers ATP release from pFRG/RTN astrocytes, potentiating respiratory center activity. Furthermore, astrocyte-specific Trpa1 disruption in a mouse brainstem-spinal cord preparation impedes the amplitude augmentation of the central autonomic respiratory output during hypoxia. Thus, reversible coupling of the
TRPA1
channels with O
2
-dependent protein translocation allows astrocytes to act as acute hypoxia sensors in the medullary respiratory center.
...
PMID:O
2
-Dependent Protein Internalization Underlies Astrocytic Sensing of Acute Hypoxia by Restricting Multimodal TRPA1 Channel Responses. 3267 97
