Targeting MTHFD2 in acute myeloid leukemia

Yana Pikman; Alexandre Puissant; Gabriela Alexe; Andrew Furman; Liying M. Chen; Stacey M. Frumm; Linda S. Ross; Nina Fenouille; Christopher F. Bassil; Caroline A. Lewis; Azucena Ramos; Joshua Gould; Richard M. Stone; Daniel J. DeAngelo; Ilene Galinsky; Clary B. Clish; Andrew L. Kung; Michael T. Hemann; Matthew G. Vander Heiden; Versha Banerji; Kimberly Stegmaier

doi:10.1084/jem.20151574

Targeting MTHFD2 in acute myeloid leukemia

Yana Pikman(Boston Children's Hospital), Alexandre Puissant(Boston Children's Hospital), Gabriela Alexe(Broad Institute), Andrew Furman(Boston Children's Hospital), Liying M. Chen(Boston Children's Hospital), Stacey M. Frumm(Boston Children's Hospital), Linda S. Ross(Boston Children's Hospital), Nina Fenouille(Massachusetts Institute of Technology), Christopher F. Bassil(Boston Children's Hospital), Caroline A. Lewis(Massachusetts Institute of Technology), Azucena Ramos(Massachusetts Institute of Technology), Joshua Gould(Broad Institute), Richard M. Stone(Dana-Farber Cancer Institute), Daniel J. DeAngelo(Dana-Farber Cancer Institute), Ilene Galinsky(Dana-Farber Cancer Institute), Clary B. Clish(Broad Institute), Andrew L. Kung(Columbia University Irving Medical Center), Michael T. Hemann(Massachusetts Institute of Technology), Matthew G. Vander Heiden(Broad Institute), Versha Banerji(Boston Children's Hospital), Kimberly Stegmaier(Broad Institute)

The Journal of Experimental Medicine

June 20, 2016

10.1084/jem.20151574

Cited by 165Open Access

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Abstract

Drugs targeting metabolism have formed the backbone of therapy for some cancers. We sought to identify new such targets in acute myeloid leukemia (AML). The one-carbon folate pathway, specifically methylenetetrahydrofolate dehydrogenase-cyclohydrolase 2 (MTHFD2), emerged as a top candidate in our analyses. MTHFD2 is the most differentially expressed metabolic enzyme in cancer versus normal cells. Knockdown of MTHFD2 in AML cells decreased growth, induced differentiation, and impaired colony formation in primary AML blasts. In human xenograft and MLL-AF9 mouse leukemia models, MTHFD2 suppression decreased leukemia burden and prolonged survival. Based upon primary patient AML data and functional genomic screening, we determined that FLT3-ITD is a biomarker of response to MTHFD2 suppression. Mechanistically, MYC regulates the expression of MTHFD2, and MTHFD2 knockdown suppresses the TCA cycle. This study supports the therapeutic targeting of MTHFD2 in AML.

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