Lovastatin inhibits erythroleukemia progression through KLF2-mediated suppression of MAPK/ERK signaling.

BACKGROUND: Lovastatin, an HMG-CoA inhibitor and an effective cholesterol lowering drug, exhibits anti-neoplastic activity towards several types of cancer, although the underlying mechanism is still not fully understood. Herein, we investigated mechanism of growth inhibition of leukemic cells by lovastatin. METHODS: RNAseq analysis was used to explore the effect of lovastatin on gene expression in leukemic cells. An animal model of leukemia was used to test the effect of this statin in vivo. FAM83A and DDIT4 expression was knocked-downed in leukemia cells via lentivirus-shRNA. Western blotting, RT-qPCR, cell cycle analysis and apoptosis assays were used to determine the effect of lovastatin-induced growth suppression in leukemic cells in vitro. RESULTS: Lovastatin treatment strongly inhibited cancer progression in a mouse model of erythroleukemia induced by Friend virus. In tissue culture, lovastatin inhibited cell proliferation through induction of G1 phase cell cycle arrest and apoptosis. Interestingly, lovastatin induced most known genes associated with cholesterol biosynthesis in leukemic cells. Moreover, it suppressed ERK1/2 phosphorylation by downregulating FAM83A and DDIT4, two mediators of MAP-Kinase signaling. RNAseq analysis of lovastatin treated leukemic cells revealed a strong induction of the tumor suppressor gene KLF2. Accordingly, lentivirus-mediated knockdown of KLF2 antagonized leukemia cell suppression induced by lovastatin, associated with higher ERK1/2 phosphorylation compared to control. We further show that KLF2 induction by lovastatin is responsible for lower expression of the FAM83A and DDIT4 oncogenes, involved in the activation of ERK1/2. KLF2 activation by lovastatin also activated a subset of cholesterol biosynthesis genes that may further contribute to leukemia suppression. CONCLUSIONS: These results implicate KLF2-mediated FAM83A/DDIT4/MAPK suppression and activation of cholesterol biosynthesis as the mechanism of leukemia cell growth inhibition by lovastatin.

FLI1 accelerates leukemogenesis through transcriptional regulation of pyruvate kinase-L/R and other glycolytic genes.

In cancer cells, multiple oncogenes and tumor suppressors control glycolysis to sustain rapid proliferation. The ETS-related transcription factor Fli1 plays a critical role in the induction and progression of leukemia, yet, the underlying mechanism of this oncogenic event is still not fully understood. In this study, RNAseq analysis of FLI1-depleted human leukemic cells revealed transcriptional suppression of the PKLR gene and activation of multiple glycolytic genes, such as PKM1/2. Pharmacological inhibition of glycolysis by PKM2 inhibitor, Shikonin, significantly suppressed leukemic cell proliferation. FLI1 directly binds to the PKLR promoter, leading to the suppression of this inhibitor of glycolysis. In accordance, shRNA-mediated depletion of PKLR in leukemic HEL cells expressing high levels of FLI1 accelerated leukemia proliferation, pointing for the first time to its tumor suppressor function. PKLR knockdown also led to downregulation of the erythroid markers EPOR, HBA1, and HBA2 and suppression of erythroid differentiation. Interestingly, silencing of PKLR in HEL cells significantly increased FLI1 expression, which was associated with faster proliferation in culture. In FLI1-expressing leukemic cells, lower PKLR expression was associated with higher expression of PKM1 and PKM2, which promote aerobic glycolysis. Finally, injection of pyruvate, a known inhibitor of glycolysis, into leukemia mice significantly suppressed leukemogenesis. These results demonstrate that FLI1 promotes leukemia in part by inducing glycolysis, implicates PKLR in erythroid differentiation, and suggests that targeting glycolysis may be an attractive therapeutic strategy for cancers driven by FLI1 overexpression.

FLI1 regulates inflammation-associated genes to accelerate leukemogenesis.

Inflammation plays a critical role in cancer initiation and progression, and is induced by inflammatory factors that are direct target of oncogenes and tumor suppressors. The ETS related transcription factor Fli-1 is involved in the induction and progression of various cancers; yet its role in inflammation is not well-defined. Using RNAseq analysis, we herein demonstrate that FLI1 induces the inflammatory pathway in erythroleukemia cells. Majority of genes within the TNF signaling pathway including TNF and IL1B were identified as transcriptional targets of FLI1. TNF expression is indirectly regulated by FLI1 through upregulation of another ETS related oncogene, SPI1/PU.1. Pharmacological inhibition of TNF significantly inhibited leukemia cell proliferation in culture. In contrast, IL1B expression is directly regulated by FLI1 through promoter binding and transcriptional activation. The secreted factor IL1B binds its canonical receptors to accelerate cancer progression through changes in the surrounding tumor microenvironment, fostering cell survival, proliferation and migration. Through network analysis, we identified IL1B-interacting genes whose expression is also regulated by FLI1. Among these, IL1B-interacting proteins, FOS, JUN, JUNB and CASP1 are negatively regulated by FLI1. Treatment of leukemia cells with inhibitors of AP1 (TAN IIA) and CASP1 (765VX) significantly accelerated FLI1-dependent leukemia progression. These results emphasize the significance of FLI1 in regulating the inflammatory pathway. Targeting these inflammatory genes downstream of FLI1 offers a novel strategy to treat leukemic progression associated with overexpression of this oncogenic ETS transcription factor.