Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase

Christian Frezza; Liang Zheng; Ori Folger; Kartik N. Rajagopalan; Elaine D. MacKenzie; Livnat Jerby; Massimo Micaroni; Barbara Chaneton; Julie Adam; Ann Hedley; Gabriela Kalna; Ian P M Tomlinson; Patrick J. Pollard; Dave G. Watson; Ralph J. Deberardinis; Tomer Shlomi; Eytan Ruppin; Eyal Gottlieb

doi:10.1038/nature10363

Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase

Christian Frezza, Liang Zheng, Ori Folger, Kartik N. Rajagopalan, Elaine D. MacKenzie, Livnat Jerby, Massimo Micaroni, Barbara Chaneton, Julie Adam, Ann Hedley, Gabriela Kalna, Ian P M Tomlinson, Patrick J. Pollard, Dave G. Watson, Ralph J. Deberardinis, Tomer Shlomi, Eytan Ruppin, Eyal Gottlieb

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Abstract

Fumarate hydratase (FH) is an enzyme of the tricarboxylic acid cycle (TCA cycle) that catalyses the hydration of fumarate into malate. Germline mutations of FH are responsible for hereditary leiomyomatosis and renal-cell cancer (HLRCC)¹. It has previously been demonstrated that the absence of FH leads to the accumulation of fumarate, which activates hypoxia-inducible factors (HIFs) at normal oxygen tensions^2-4. However, so far no mechanism that explains the ability of cells to survive without a functional TCA cycle has been provided. Here we use newly characterized genetically modified kidney mouse cells in which Fh1 has been deleted, and apply a newly developed computer model of the metabolism of these cells to predict and experimentally validate a linear metabolic pathway beginning with glutamine uptake and ending with bilirubin excretion from Fh1-deficient cells. This pathway, which involves the biosynthesis and degradation of haem, enables Fh1-deficient cells to use the accumulated TCA cycle metabolites and permits partial mitochondrial NADH production. We predicted and confirmed that targeting this pathway would render Fh1-deficient cells non-viable, while sparing wild-type Fh1-containing cells. This work goes beyond identifying a metabolic pathway that is induced in Fh1-deficient cells to demonstrate that inhibition of haem oxygenation is synthetically lethal when combined with Fh1 deficiency, providing a new potential target for treating HLRCC patients.

Original language	English (US)
Pages (from-to)	225-228
Number of pages	4
Journal	Nature
Volume	477
Issue number	7363
DOIs	https://doi.org/10.1038/nature10363
State	Published - Sep 8 2011

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Frezza, C., Zheng, L., Folger, O., Rajagopalan, K. N., MacKenzie, E. D., Jerby, L., Micaroni, M., Chaneton, B., Adam, J., Hedley, A., Kalna, G., Tomlinson, I. P. M., Pollard, P. J., Watson, D. G., Deberardinis, R. J., Shlomi, T., Ruppin, E., & Gottlieb, E. (2011). Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase. Nature, 477(7363), 225-228. https://doi.org/10.1038/nature10363

Frezza, C, Zheng, L, Folger, O, Rajagopalan, KN, MacKenzie, ED, Jerby, L, Micaroni, M, Chaneton, B, Adam, J, Hedley, A, Kalna, G, Tomlinson, IPM, Pollard, PJ, Watson, DG, Deberardinis, RJ, Shlomi, T, Ruppin, E & Gottlieb, E 2011, 'Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase', Nature, vol. 477, no. 7363, pp. 225-228. https://doi.org/10.1038/nature10363

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title = "Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase",

abstract = "Fumarate hydratase (FH) is an enzyme of the tricarboxylic acid cycle (TCA cycle) that catalyses the hydration of fumarate into malate. Germline mutations of FH are responsible for hereditary leiomyomatosis and renal-cell cancer (HLRCC)1. It has previously been demonstrated that the absence of FH leads to the accumulation of fumarate, which activates hypoxia-inducible factors (HIFs) at normal oxygen tensions2-4. However, so far no mechanism that explains the ability of cells to survive without a functional TCA cycle has been provided. Here we use newly characterized genetically modified kidney mouse cells in which Fh1 has been deleted, and apply a newly developed computer model of the metabolism of these cells to predict and experimentally validate a linear metabolic pathway beginning with glutamine uptake and ending with bilirubin excretion from Fh1-deficient cells. This pathway, which involves the biosynthesis and degradation of haem, enables Fh1-deficient cells to use the accumulated TCA cycle metabolites and permits partial mitochondrial NADH production. We predicted and confirmed that targeting this pathway would render Fh1-deficient cells non-viable, while sparing wild-type Fh1-containing cells. This work goes beyond identifying a metabolic pathway that is induced in Fh1-deficient cells to demonstrate that inhibition of haem oxygenation is synthetically lethal when combined with Fh1 deficiency, providing a new potential target for treating HLRCC patients.",

author = "Christian Frezza and Liang Zheng and Ori Folger and Rajagopalan, {Kartik N.} and MacKenzie, {Elaine D.} and Livnat Jerby and Massimo Micaroni and Barbara Chaneton and Julie Adam and Ann Hedley and Gabriela Kalna and Tomlinson, {Ian P M} and Pollard, {Patrick J.} and Watson, {Dave G.} and Deberardinis, {Ralph J.} and Tomer Shlomi and Eytan Ruppin and Eyal Gottlieb",

note = "Funding Information: AcknowledgementsThis workwas supportedbyCancerResearchUK.Wewouldlike to acknowledge the Patterson Institute for Cancer Research for the Exon Array analysis. C.F. is supported by an EMBO long term fellowship (ALTF330). P.J.P. is in receipt of a Beit Memorial Fellowship funded by the Wellcome Trust (WT091112MA). D.G.W. and L.Z. would like to acknowledge SULSA (Scottish Universities Life Science Alliance). R.J.D. and K.N.R. are supported by the NIH (DK072565-05) and the Cancer Prevention and Research Institute of Texas (HIRP100437-01). O.F., T.S. and E.R. are supported by the Israel Science Foundation (ISF) and the Israel Cancer Research Foundation. L.J. is supported by the Edmond J. Safra Bioinformatics program at TAU. We thank UOB Tumor Cell Line Repository and W. Marston Linehan for providing us with the UOK262 cell lines, and A. King for editorial work.",

year = "2011",

month = sep,

day = "8",

doi = "10.1038/nature10363",

language = "English (US)",

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journal = "Nature",

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T1 - Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase

AU - Frezza, Christian

AU - Zheng, Liang

AU - Folger, Ori

AU - Rajagopalan, Kartik N.

AU - MacKenzie, Elaine D.

AU - Jerby, Livnat

AU - Micaroni, Massimo

AU - Chaneton, Barbara

AU - Adam, Julie

AU - Hedley, Ann

AU - Kalna, Gabriela

AU - Tomlinson, Ian P M

AU - Pollard, Patrick J.

AU - Watson, Dave G.

AU - Deberardinis, Ralph J.

AU - Shlomi, Tomer

AU - Ruppin, Eytan

AU - Gottlieb, Eyal

N1 - Funding Information: AcknowledgementsThis workwas supportedbyCancerResearchUK.Wewouldlike to acknowledge the Patterson Institute for Cancer Research for the Exon Array analysis. C.F. is supported by an EMBO long term fellowship (ALTF330). P.J.P. is in receipt of a Beit Memorial Fellowship funded by the Wellcome Trust (WT091112MA). D.G.W. and L.Z. would like to acknowledge SULSA (Scottish Universities Life Science Alliance). R.J.D. and K.N.R. are supported by the NIH (DK072565-05) and the Cancer Prevention and Research Institute of Texas (HIRP100437-01). O.F., T.S. and E.R. are supported by the Israel Science Foundation (ISF) and the Israel Cancer Research Foundation. L.J. is supported by the Edmond J. Safra Bioinformatics program at TAU. We thank UOB Tumor Cell Line Repository and W. Marston Linehan for providing us with the UOK262 cell lines, and A. King for editorial work.

PY - 2011/9/8

Y1 - 2011/9/8

N2 - Fumarate hydratase (FH) is an enzyme of the tricarboxylic acid cycle (TCA cycle) that catalyses the hydration of fumarate into malate. Germline mutations of FH are responsible for hereditary leiomyomatosis and renal-cell cancer (HLRCC)1. It has previously been demonstrated that the absence of FH leads to the accumulation of fumarate, which activates hypoxia-inducible factors (HIFs) at normal oxygen tensions2-4. However, so far no mechanism that explains the ability of cells to survive without a functional TCA cycle has been provided. Here we use newly characterized genetically modified kidney mouse cells in which Fh1 has been deleted, and apply a newly developed computer model of the metabolism of these cells to predict and experimentally validate a linear metabolic pathway beginning with glutamine uptake and ending with bilirubin excretion from Fh1-deficient cells. This pathway, which involves the biosynthesis and degradation of haem, enables Fh1-deficient cells to use the accumulated TCA cycle metabolites and permits partial mitochondrial NADH production. We predicted and confirmed that targeting this pathway would render Fh1-deficient cells non-viable, while sparing wild-type Fh1-containing cells. This work goes beyond identifying a metabolic pathway that is induced in Fh1-deficient cells to demonstrate that inhibition of haem oxygenation is synthetically lethal when combined with Fh1 deficiency, providing a new potential target for treating HLRCC patients.

AB - Fumarate hydratase (FH) is an enzyme of the tricarboxylic acid cycle (TCA cycle) that catalyses the hydration of fumarate into malate. Germline mutations of FH are responsible for hereditary leiomyomatosis and renal-cell cancer (HLRCC)1. It has previously been demonstrated that the absence of FH leads to the accumulation of fumarate, which activates hypoxia-inducible factors (HIFs) at normal oxygen tensions2-4. However, so far no mechanism that explains the ability of cells to survive without a functional TCA cycle has been provided. Here we use newly characterized genetically modified kidney mouse cells in which Fh1 has been deleted, and apply a newly developed computer model of the metabolism of these cells to predict and experimentally validate a linear metabolic pathway beginning with glutamine uptake and ending with bilirubin excretion from Fh1-deficient cells. This pathway, which involves the biosynthesis and degradation of haem, enables Fh1-deficient cells to use the accumulated TCA cycle metabolites and permits partial mitochondrial NADH production. We predicted and confirmed that targeting this pathway would render Fh1-deficient cells non-viable, while sparing wild-type Fh1-containing cells. This work goes beyond identifying a metabolic pathway that is induced in Fh1-deficient cells to demonstrate that inhibition of haem oxygenation is synthetically lethal when combined with Fh1 deficiency, providing a new potential target for treating HLRCC patients.

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Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase

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