Isolation and characterisation of Kasumi-1 human myeloid leukaemia cell line resistant to tumour necrosis factor alpha-induced apoptosis

Cinobufagin inhibits proliferation of acute myeloid leukaemia cells by repressing c-Myc pathway-associated genes

Cinobufagin is a cardiotoxic bufanolide steroid secreted by the Asiatic toad, Bufo gargarizans. Bufanolides inhibit Na⁺/K⁺ ATPase and have similar effects as cardiac glycosides, such as digitoxin or ouabain derived from toxic herbs. Recently, the anti-cancer effects of bufanolides have gained attention, however the underlying molecular mechanisms remain unclear. Selecting cinobufagin as a candidate anti-leukaemia agent, we here conducted transcriptomic analyses on the effect of cinobufagin on human acute myeloid leukaemia (AML) cell lines, HL60 and Kasumi-1. Flow cytometry analysis showed that cinobufagin induced apoptosis in both cell lines. RNA-sequencing (RNA-seq) of the two cell lines treated with cinobufagin revealed commonly downregulated genes with enrichment in the term "Myc active pathway" according to Gene Ontology (GO) analysis. Gene Set Enrichment Analysis (GSEA) of genes downregulated by cinobufagin also showed "MYC_TARGETS_V2" with the highest normalised enrichment score (NES) in both cell lines. In contrast, hallmarks such as "TNFA_SIGNALING_VIA_NFKB", "APOPTOSIS", and "TGF_BETA_SIGNALING" were significantly enriched as upregulated gene sets. Epigenetic analysis using chromatin immunoprecipitation and sequencing (ChIP-seq) confirmed that genes encoding cell death-related signalling molecules were upregulated by gain of H3K27ac, whereas downregulation of c-Myc-related genes was not accompanied by H3K27ac alteration. Cinobufagin is an anti-proliferative natural compound with c-Myc-inhibiting and epigenetic-modulating activity in acute myeloid leukaemia.

TNFalpha accelerates monocyte to endothelial transdifferentiation in tumors by the induction of integrin alpha5 expression and adhesion to fibronectin

Tumor-associated myeloid cells are believed to promote tumor development by stimulating tumor growth, angiogenesis, invasion, and metastasis. Tumor-associated myeloid cells that coexpress endothelial and myeloid markers represent a proangiogenic subpopulation known as vascular leukocytes. Recently, we and others had shown that tumor-derived TNFα promotes local tumor growth and vascularity. Our data suggested that tumor growth is in part due to TNFα-mediated increased numbers of tumor-associated vascular leukocytes (i.e., myeloid-endothelial biphenotypic cells). The work detailed herein explored the mechanism by which TNFα mediates endothelial differentiation of myeloid cells. Our studies showed that fibronectin is a robust facilitator of endothelial differentiation of blood mononuclear cells in vitro. We have found that TNFα treatment of monocytes significantly increased expression of α(5)β(1) integrin, a major fibronectin receptor enriched on endothelial cells, leading to a consequent fourfold increase in fibronectin adhesion. Furthermore, TNFα-treated monocytes upregulated expression of endothelial markers, flk-1(VEGFR2/KDR) and VE-cadherin. Integrin α(5) subunit inhibitory antibodies blocked adhesion to fibronectin as well as consequent upregulation of flk-1 and VE-cadherin transcripts, implying a role for outside-in signaling by the α(5)β(1) integrin after binding fibronectin. Finally, treatment of mouse tumors with anti-α(5) antibodies reduced accumulation of tumor vascular leukocytes in vivo. Our studies suggest that tumor cell-derived TNFα constitutes a tumor microenvironment signal that promotes differentiation of tumor-associated monocytes toward a proangiogenic/provasculogenic myeloid-endothelial phenotype via upregulation of the fibronectin receptor α(5)β(1).

Sphingomyelin potentiates chemotherapy of human cancer xenografts

We propose that one manifestation of altered sphingolipid metabolism within tumor cells may be a reduced sensitivity to anti-cancer therapies because of an inability to produce a sufficient apoptotic signal via sphingomyelin hydrolysis to ceramide. If so, then sphingomyelin administration could reverse this effect and increase a tumor's sensitivity to chemotherapy. In vivo, intravenous sphingomyelin (10 mg/day, 7 days) potentiated 5-fluorouracil chemotherapy (0.45 mg/day, 5 days) when co-administered to HT29 human colonic xenograft-bearing nude mice. In vitro, sphingomyelin (SM) at its maximum tolerated concentration increased 5-fluorouracil and doxorubicin sensitivity of HCT15 and MOSER (1 mg/ml SM) and LS174T and SW480 human colonic tumor cells (0.1 mg/ml) approximately 100-300%. At 1 mg/ml SM, however, no effect was seen using HT29, LoVo and WiDr cells. There was no sensitization of normal human umbilical cord endothelial cells. Thus, sphingomyelin co-administration may be one method to improve the selective efficacy of chemotherapy in some tumors, possibly through enhancement of the apoptotic response.