Arsenic trioxide induces accumulation of cytotoxic levels of ceramide in acute promyelocytic leukemia and adult T-cell leukemia/lymphoma cells through de novo ceramide synthesis and inhibition of glucosylceramide synthase activity

Background and Objectives Arsenic trioxide (ATO) is an effective treatment for acute promyelocytic leukemia (APL) and potentially for human T-cell leukemia virus type I (HTLV-I) associated adult T-cell leukemia/lymphoma (ATL). Many cytotoxic drugs induce apoptosis through the generation and accumulation of the sphingolipid breakdown product, ceramide, a coordinator of the cellular response to stress. We, therefore, investigated the contribution of ceramide to the mechanism of action of ATO in APL and ATL.Design and Methods A human APL-derived cell line (NB4), various ATL-derived lines and an HTLV-I-negative malignant T-cell line were cultured and treated with ATO. Growth and apoptosis assays were conducted. Measurements were made of ceramide, diacylglycerol, sphingomyelinase activity, sphingomyelin mass, glucosylceramide synthase activity and the de novo ceramide synthesis.Results Treatment of APL and ATL-derived cells with a clinically achievable concentration of ATO induced accumulation of cytotoxic levels of ceramide. The effects of ATO on ceramide levels in APL cells were more potent than those of all-trans retinoic acid (ATRA). ATO downregulated neutral sphingomyelinase activity. In contrast to the effect of ATRA, ATO-induced ceramide accumulation was not due to induction of acidic sphingomyelinase, but rather resulted from both de novo ceramide synthesis and inhibition of glucosylceramide synthase activity. Interestingly, the effects of ATO on de novo ceramide synthesis were similar in APL and ATL-derived cells despite the defective pathway in ATL cells.Interpretation and Conclusions These results indicate that ATO-induced ceramide accumulation may represent a general mediator of the effects of ATO, which paves the way for new therapeutic interventions that target the metabolic pathway of this important sphingolipid secondary messenger

Differential sensitivity of Src-family kinases to activation by SH3 domain displacement

Src-family kinases (SFKs) are non-receptor protein-tyrosine kinases involved in a variety of signaling pathways in virtually every cell type. The SFKs share a common negative regulatory mechanism that involves intramolecular interactions of the SH3 domain with the PPII helix formed by the SH2-kinase linker as well as the SH2 domain with a conserved phosphotyrosine residue in the C-terminal tail. Growing evidence suggests that individual SFKs may exhibit distinct activation mechanisms dictated by the relative strengths of these intramolecular interactions. To elucidate the role of the SH3:linker interaction in the regulation of individual SFKs, we used a synthetic SH3 domain-binding peptide (VSL12) to probe the sensitivity of downregulated c-Src, Hck, Lyn and Fyn to SH3-based activation in a kinetic kinase assay. All four SFKs responded to VSL12 binding with enhanced kinase activity, demonstrating a conserved role for SH3:linker interaction in the control of catalytic function. However, the sensitivity and extent of SH3-based activation varied over a wide range. In addition, autophosphorylation of the activation loops of c-Src and Hck did not override regulatory control by SH3:linker displacement, demonstrating that these modes of activation are independent. Our results show that despite the similarity of their downregulated conformations, individual Src-family members show diverse responses to activation by domain displacement which may reflect their adaptation to specific signaling environments in vivo. © 2014 Moroco et al

N-Myristoylated c-Abl Tyrosine Kinase Localizes to the Endoplasmic Reticulum upon Binding to an Allosteric Inhibitor*

Allosteric kinase inhibitors hold promise for revealing unique features of kinases that may not be apparent using conventional ATP-competitive inhibitors. Here we explore the activity of a previously reported allosteric inhibitor of BCR-Abl kinase, GNF-2, against two cellular isoforms of Abl tyrosine kinase: one that carries a myristate in the N terminus and the other that is deficient in N-myristoylation. Our results show that GNF-2 inhibits the kinase activity of non-myristoylated c-Abl more potently than that of myristoylated c-Abl by binding to the myristate-binding pocket in the C-lobe of the kinase domain. Unexpectedly, indirect immunofluorescence reveals a translocation of myristoylated c-Abl to the endoplasmic reticulum in GNF-2-treated cells, whereas GNF-2 has no detectable effect on the localization of non-myristoylated c-Abl. These results indicate that GNF-2 competes with the NH2-terminal myristate for binding to the c-Abl kinase myristate-binding pocket and that the exposed myristoyl group accounts for the localization to the endoplasmic reticulum. We also demonstrate that GNF-2 can inhibit enzymatic and cellular kinase activity of Arg, a kinase highly homologous to c-Abl, which is also likely to be regulated through intramolecular binding of an NH2-terminal myristate lipid. These results suggest that non-ATP-competitive inhibitors, such as GNF-2, can serve as chemical tools that can discriminate between c-Abl isoform-specific behaviors