N-acetylcysteine, xCT and suppression of Maxi-chloride channel activity in human placenta
N-acetylcysteine, xCT and suppression of Maxi-chloride channel activity in human placenta
Introduction: Placental oxidative stress features in pregnancy pathologies but in clinical trials antioxidant supplementation has not improved outcomes. N-acetylcysteine (NAC) stimulates glutathione production and is proposed as a therapeutic agent in pregnancy. However, key elements of N-acetylcysteine biology, including its cellular uptake mechanism, remains unclear. This study explores how the cystine/glutamate transporter xCT may mediate N-acetylcysteine uptake and how N-acetylcysteine alters placental redox status. Methods: The involvement of xCT in NAC uptake by the human placenta was studied in perfused placenta and Xenopus oocytes. The effect of short-term N-acetylcysteine exposure on the placental villous proteome was determined using LC-MS. The effect of N-acetylcysteine on Maxi-chloride channel activity was investigated in perfused placenta, villous fragments and cell culture. Results: Maternoplacental N-acetylcysteine administration stimulated intracellular glutamate efflux suggesting a role of the exchange transporter xCT, which was localised to the microvillous membrane of the placental syncytiotrophoblast. Placental exposure to a bolus of N-acetylcysteine inhibited subsequent activation of the redox sensitive Maxi-chloride channel independently of glutathione synthesis. Stable isotope quantitative proteomics of placental villi treated with N-acetylcysteine demonstrated changes in pathways associated with oxidative stress, apoptosis and the acute phase response. Discussion: This study suggests that xCT mediates N-acetylcysteine uptake into the placenta and that N-acetylcysteine treatment of placental tissue alters the placental proteome while regulating the redox sensitive Maxi-chloride channel. Interestingly N-acetylcysteine had antioxidant effects independent of the glutathione pathway. Effective placental antioxidant therapy in pregnancy may require maintaining the balance between normalising redox status without inhibiting physiological redox signalling.
Antioxidant, Membrane transport, Redox
46-55
Lofthouse, Emma
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Manousopoulou, Antigoni
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Cleal, Jane
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O'Kelly, Ita M
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Poore, Kirsten
b9529ba3-6432-4935-b8fd-6e382f11f0ad
Garbis, Spiros
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Lewis, Rohan
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July 2021
Lofthouse, Emma
c4004ff1-2ed3-4b80-9ade-583c742de59c
Manousopoulou, Antigoni
9a5e4e75-cea9-4d0b-91c8-0fa2af02632f
Cleal, Jane
18cfd2c1-bd86-4a13-b38f-c321af56da66
O'Kelly, Ita M
e640f28a-42f0-48a6-9ce2-cb5a85d08c66
Poore, Kirsten
b9529ba3-6432-4935-b8fd-6e382f11f0ad
Garbis, Spiros
7067fd19-50c9-4d42-9611-f370289470bd
Lewis, Rohan
caaeb97d-ea69-4f7b-8adb-5fa25e2d3502
Lofthouse, Emma, Manousopoulou, Antigoni, Cleal, Jane, O'Kelly, Ita M, Poore, Kirsten, Garbis, Spiros and Lewis, Rohan
(2021)
N-acetylcysteine, xCT and suppression of Maxi-chloride channel activity in human placenta.
Placenta, 110, .
(doi:10.1016/j.placenta.2021.05.009).
Abstract
Introduction: Placental oxidative stress features in pregnancy pathologies but in clinical trials antioxidant supplementation has not improved outcomes. N-acetylcysteine (NAC) stimulates glutathione production and is proposed as a therapeutic agent in pregnancy. However, key elements of N-acetylcysteine biology, including its cellular uptake mechanism, remains unclear. This study explores how the cystine/glutamate transporter xCT may mediate N-acetylcysteine uptake and how N-acetylcysteine alters placental redox status. Methods: The involvement of xCT in NAC uptake by the human placenta was studied in perfused placenta and Xenopus oocytes. The effect of short-term N-acetylcysteine exposure on the placental villous proteome was determined using LC-MS. The effect of N-acetylcysteine on Maxi-chloride channel activity was investigated in perfused placenta, villous fragments and cell culture. Results: Maternoplacental N-acetylcysteine administration stimulated intracellular glutamate efflux suggesting a role of the exchange transporter xCT, which was localised to the microvillous membrane of the placental syncytiotrophoblast. Placental exposure to a bolus of N-acetylcysteine inhibited subsequent activation of the redox sensitive Maxi-chloride channel independently of glutathione synthesis. Stable isotope quantitative proteomics of placental villi treated with N-acetylcysteine demonstrated changes in pathways associated with oxidative stress, apoptosis and the acute phase response. Discussion: This study suggests that xCT mediates N-acetylcysteine uptake into the placenta and that N-acetylcysteine treatment of placental tissue alters the placental proteome while regulating the redox sensitive Maxi-chloride channel. Interestingly N-acetylcysteine had antioxidant effects independent of the glutathione pathway. Effective placental antioxidant therapy in pregnancy may require maintaining the balance between normalising redox status without inhibiting physiological redox signalling.
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N_acetylcysteine_xCT_and_suppression_of_Maxi_chloride_channel_activity_in_human_placenta
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Lofthouse 2021 N acetylcycsteine, xCT Placenta
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N-acetylcysteine, xCT and suppression of Maxi-chloride channel activity in human placenta
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Authors accepted manuscript N-acetylcysteine, xCT and suppression of Maxi-chloride channel activity in human placenta
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Accepted/In Press date: 26 May 2021
e-pub ahead of print date: 5 June 2021
Published date: July 2021
Additional Information:
Funding Information:
We would like to thank The Gerald Kerkut Charitable Trust and the BBSRC (BB/L020823/1) for their funding and the midwives and patients at the Princess Anne Hospital, Southampton for their help in collecting placentas.
Publisher Copyright:
© 2021 Elsevier Ltd
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
Keywords:
Antioxidant, Membrane transport, Redox
Identifiers
Local EPrints ID: 453093
URI: http://eprints.soton.ac.uk/id/eprint/453093
ISSN: 0143-4004
PURE UUID: 59587cf4-c673-4aa5-9f99-13332cb539e2
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Date deposited: 07 Jan 2022 19:35
Last modified: 17 Mar 2024 06:38
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Contributors
Author:
Emma Lofthouse
Author:
Antigoni Manousopoulou
Author:
Ita M O'Kelly
Author:
Spiros Garbis
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