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Literature DB >> 27055871

Re-activation of mitochondrial apoptosis inhibits T-cell lymphoma survival and treatment resistance.

S Spinner¹, G Crispatzu², J-H Yi³, E Munkhbaatar¹, P Mayer², U Höckendorf¹, N Müller¹, Z Li¹, T Schader³, H Bendz¹, S Hartmann³, M Yabal¹, K Pechloff^4,5, M Heikenwalder^6,7, G L Kelly^8,9, A Strasser^8,9, C Peschel¹, M-L Hansmann³, J Ruland⁴, U Keller¹, S Newrzela³, M Herling², P J Jost^1,5.

Abstract

T lymphocyte non-Hodgkin's lymphoma (T-NHL) represents an aggressive and largely therapy-resistant subtype of lymphoid malignancies. As deregulated apoptosis is a frequent hallmark of lymphomagenesis, we analyzed gene expression profiles and protein levels of primary human T-NHL samples for various apoptotic regulators. We identified the apoptotic regulator MCL-1 as the only pro-survival BCL-2 family member to be highly expressed throughout all human T-NHL subtypes. Functional validation of pro-survival protein members of the BCL-2 family in two independent T-NHL mouse models identified that the partial loss of Mcl-1 significantly delayed T-NHL development in vivo. Moreover, the inducible reduction of MCL-1 protein levels in lymphoma-burdened mice severely impaired the continued survival of T-NHL cells, increased their susceptibility to chemotherapeutics and delayed lymphoma progression. Lymphoma viability remained unaffected by the genetic deletion or pharmacological inhibition of all alternative BCL-2 family members. Consistent with a therapeutic window for MCL-1 treatment within the context of the whole organism, we observed an only minimal toxicity after systemic heterozygous loss of Mcl-1 in vivo. We conclude that re-activation of mitochondrial apoptosis by blockade of MCL-1 represents a promising therapeutic strategy to treat T-cell lymphoma.

Entities: Disease Gene Species

Mesh：

Substances：

Year: 2016 PMID： 27055871 DOI： 10.1038/leu.2016.49

Source DB: PubMed Journal: Leukemia ISSN： 0887-6924 Impact factor: 11.528

66 in total

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