Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models

Saravanan S. Karuppagounder; Ishraq Alim; Soah J. Khim; Megan W. Bourassa; Sama F. Sleiman; Roseleen John; Cyrille C. Thinnes; Tzu Lan Yeh; Marina Demetriades; Sandra Neitemeier; Dana Cruz; Irina Gazaryan; David W. Killilea; Lewis Morgenstern; Guohua Xi; Richard F. Keep; Timothy Schallert; Ryan V. Tappero; Jian Zhong; Sunghee Cho; Frederick R. Maxfield; Theodore R. Holman; Carsten Culmsee; Guo Hua Fong; Yijing Su; Guo Li Ming; Hongjun Song; John W. Cave; Christopher J. Schofield; Frederick Colbourne; Giovanni Coppola; Rajiv R. Ratan

doi:10.1126/scitranslmed.aac6008

Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models

Saravanan S. Karuppagounder, Ishraq Alim, Soah J. Khim, Megan W. Bourassa, Sama F. Sleiman, Roseleen John, Cyrille C. Thinnes, Tzu Lan Yeh, Marina Demetriades, Sandra Neitemeier, Dana Cruz, Irina Gazaryan, David W. Killilea, Lewis Morgenstern, Guohua Xi, Richard F. Keep, Timothy Schallert, Ryan V. Tappero, Jian Zhong, Sunghee ChoFrederick R. Maxfield, Theodore R. Holman, Carsten Culmsee, Guo Hua Fong, Yijing Su, Guo Li Ming, Hongjun Song, John W. Cave, Christopher J. Schofield, Frederick Colbourne, Giovanni Coppola, Rajiv R. Ratan

School of Medicine

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68 Scopus citations

Abstract

Disability or death due to intracerebral hemorrhage (ICH) is attributed to blood lysis, liberation of iron, and consequent oxidative stress. Iron chelators bind to free iron and prevent neuronal death induced by oxidative stress and disability due to ICH, but the mechanisms for this effect remain unclear. We show that the hypoxia-inducible factor prolyl hydroxylase domain (HIF-PHD) family of iron-dependent, oxygen-sensing enzymes are effectors of iron chelation. Molecular reduction of the three HIF-PHD enzyme isoforms in the mouse striatum improved functional recovery after ICH. A low-molecular-weight hydroxyquinoline inhibitor of the HIF-PHD enzymes, adaptaquin, reduced neuronal death and behavioral deficits after ICH in several rodent models without affecting total iron or zinc distribution in the brain. Unexpectedly, protection fromoxidativedeath invitroor fromICHinvivobyadaptaquinwasassociatedwithsuppression of activity of the prodeath factor ATF4 rather than activation of an HIF-dependent prosurvival pathway. Together, these findings demonstrate that brain-specific inactivation of the HIF-PHD metalloenzymes with the blood-brain barrier-permeable inhibitor adaptaquin can improve functional outcomes after ICH in several rodent models.

Original language	English (US)
Article number	328ra29
Journal	Science Translational Medicine
Volume	8
Issue number	328
DOIs	https://doi.org/10.1126/scitranslmed.aac6008
State	Published - Mar 2 2016

ASJC Scopus subject areas

General Medicine

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10.1126/scitranslmed.aac6008

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Karuppagounder, S. S., Alim, I., Khim, S. J., Bourassa, M. W., Sleiman, S. F., John, R., Thinnes, C. C., Yeh, T. L., Demetriades, M., Neitemeier, S., Cruz, D., Gazaryan, I., Killilea, D. W., Morgenstern, L., Xi, G., Keep, R. F., Schallert, T., Tappero, R. V., Zhong, J., ... Ratan, R. R. (2016). Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models. Science Translational Medicine, 8(328), Article 328ra29. https://doi.org/10.1126/scitranslmed.aac6008

Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models. / Karuppagounder, Saravanan S.; Alim, Ishraq; Khim, Soah J. et al.
In: Science Translational Medicine, Vol. 8, No. 328, 328ra29, 02.03.2016.

Research output: Contribution to journal › Article › peer-review

Karuppagounder, SS, Alim, I, Khim, SJ, Bourassa, MW, Sleiman, SF, John, R, Thinnes, CC, Yeh, TL, Demetriades, M, Neitemeier, S, Cruz, D, Gazaryan, I, Killilea, DW, Morgenstern, L, Xi, G, Keep, RF, Schallert, T, Tappero, RV, Zhong, J, Cho, S, Maxfield, FR, Holman, TR, Culmsee, C, Fong, GH, Su, Y, Ming, GL, Song, H, Cave, JW, Schofield, CJ, Colbourne, F, Coppola, G & Ratan, RR 2016, 'Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models', Science Translational Medicine, vol. 8, no. 328, 328ra29. https://doi.org/10.1126/scitranslmed.aac6008

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title = "Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models",

abstract = "Disability or death due to intracerebral hemorrhage (ICH) is attributed to blood lysis, liberation of iron, and consequent oxidative stress. Iron chelators bind to free iron and prevent neuronal death induced by oxidative stress and disability due to ICH, but the mechanisms for this effect remain unclear. We show that the hypoxia-inducible factor prolyl hydroxylase domain (HIF-PHD) family of iron-dependent, oxygen-sensing enzymes are effectors of iron chelation. Molecular reduction of the three HIF-PHD enzyme isoforms in the mouse striatum improved functional recovery after ICH. A low-molecular-weight hydroxyquinoline inhibitor of the HIF-PHD enzymes, adaptaquin, reduced neuronal death and behavioral deficits after ICH in several rodent models without affecting total iron or zinc distribution in the brain. Unexpectedly, protection fromoxidativedeath invitroor fromICHinvivobyadaptaquinwasassociatedwithsuppression of activity of the prodeath factor ATF4 rather than activation of an HIF-dependent prosurvival pathway. Together, these findings demonstrate that brain-specific inactivation of the HIF-PHD metalloenzymes with the blood-brain barrier-permeable inhibitor adaptaquin can improve functional outcomes after ICH in several rodent models.",

author = "Karuppagounder, {Saravanan S.} and Ishraq Alim and Khim, {Soah J.} and Bourassa, {Megan W.} and Sleiman, {Sama F.} and Roseleen John and Thinnes, {Cyrille C.} and Yeh, {Tzu Lan} and Marina Demetriades and Sandra Neitemeier and Dana Cruz and Irina Gazaryan and Killilea, {David W.} and Lewis Morgenstern and Guohua Xi and Keep, {Richard F.} and Timothy Schallert and Tappero, {Ryan V.} and Jian Zhong and Sunghee Cho and Maxfield, {Frederick R.} and Holman, {Theodore R.} and Carsten Culmsee and Fong, {Guo Hua} and Yijing Su and Ming, {Guo Li} and Hongjun Song and Cave, {John W.} and Schofield, {Christopher J.} and Frederick Colbourne and Giovanni Coppola and Ratan, {Rajiv R.}",

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T1 - Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models

AU - Karuppagounder, Saravanan S.

AU - Alim, Ishraq

AU - Khim, Soah J.

AU - Bourassa, Megan W.

AU - Sleiman, Sama F.

AU - John, Roseleen

AU - Thinnes, Cyrille C.

AU - Yeh, Tzu Lan

AU - Demetriades, Marina

AU - Neitemeier, Sandra

AU - Cruz, Dana

AU - Gazaryan, Irina

AU - Killilea, David W.

AU - Morgenstern, Lewis

AU - Xi, Guohua

AU - Keep, Richard F.

AU - Schallert, Timothy

AU - Tappero, Ryan V.

AU - Zhong, Jian

AU - Cho, Sunghee

AU - Maxfield, Frederick R.

AU - Holman, Theodore R.

AU - Culmsee, Carsten

AU - Fong, Guo Hua

AU - Su, Yijing

AU - Ming, Guo Li

AU - Song, Hongjun

AU - Cave, John W.

AU - Schofield, Christopher J.

AU - Colbourne, Frederick

AU - Coppola, Giovanni

AU - Ratan, Rajiv R.

PY - 2016/3/2

Y1 - 2016/3/2

N2 - Disability or death due to intracerebral hemorrhage (ICH) is attributed to blood lysis, liberation of iron, and consequent oxidative stress. Iron chelators bind to free iron and prevent neuronal death induced by oxidative stress and disability due to ICH, but the mechanisms for this effect remain unclear. We show that the hypoxia-inducible factor prolyl hydroxylase domain (HIF-PHD) family of iron-dependent, oxygen-sensing enzymes are effectors of iron chelation. Molecular reduction of the three HIF-PHD enzyme isoforms in the mouse striatum improved functional recovery after ICH. A low-molecular-weight hydroxyquinoline inhibitor of the HIF-PHD enzymes, adaptaquin, reduced neuronal death and behavioral deficits after ICH in several rodent models without affecting total iron or zinc distribution in the brain. Unexpectedly, protection fromoxidativedeath invitroor fromICHinvivobyadaptaquinwasassociatedwithsuppression of activity of the prodeath factor ATF4 rather than activation of an HIF-dependent prosurvival pathway. Together, these findings demonstrate that brain-specific inactivation of the HIF-PHD metalloenzymes with the blood-brain barrier-permeable inhibitor adaptaquin can improve functional outcomes after ICH in several rodent models.

AB - Disability or death due to intracerebral hemorrhage (ICH) is attributed to blood lysis, liberation of iron, and consequent oxidative stress. Iron chelators bind to free iron and prevent neuronal death induced by oxidative stress and disability due to ICH, but the mechanisms for this effect remain unclear. We show that the hypoxia-inducible factor prolyl hydroxylase domain (HIF-PHD) family of iron-dependent, oxygen-sensing enzymes are effectors of iron chelation. Molecular reduction of the three HIF-PHD enzyme isoforms in the mouse striatum improved functional recovery after ICH. A low-molecular-weight hydroxyquinoline inhibitor of the HIF-PHD enzymes, adaptaquin, reduced neuronal death and behavioral deficits after ICH in several rodent models without affecting total iron or zinc distribution in the brain. Unexpectedly, protection fromoxidativedeath invitroor fromICHinvivobyadaptaquinwasassociatedwithsuppression of activity of the prodeath factor ATF4 rather than activation of an HIF-dependent prosurvival pathway. Together, these findings demonstrate that brain-specific inactivation of the HIF-PHD metalloenzymes with the blood-brain barrier-permeable inhibitor adaptaquin can improve functional outcomes after ICH in several rodent models.

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ER -

Therapeutic targeting of oxygen-sensing prolyl hydroxylases abrogates ATF4-dependent neuronal death and improves outcomes after brain hemorrhage in several rodent models

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