Principal component analysis uncovers cytomegalovirus-associated NK cell activation in Ph+ leukemia patients treated with dasatinib.

Dasatinib treatment markedly increases the number of large granular lymphocytes (LGLs) in a proportion of Ph+ leukemia patients, which associates with a better prognosis. The lymphocytosis is predominantly observed in cytomegalovirus (CMV)-seropositive patients, yet detectable CMV reactivation exists only in a small fraction of patients. Thus, etiology of the lymphocytosis still remains unclear. Here, we identified NK cells as the dominant LGLs expanding in dasatinib-treated patients, and applied principal component analysis (PCA) to an extensive panel of NK cell markers to explore underlying factors in NK cell activation. PCA displayed phenotypic divergence of NK cells that reflects CMV-associated differentiation and genetic differences, and the divergence was markedly augmented in CMV-seropositive dasatinib-treated patients. Notably, the CMV-associated highly differentiated status of NK cells was already observed at leukemia diagnosis, and was further enhanced after starting dasatinib in virtually all CMV-seropositive patients. Thus, the extensive characterization of NK cells by PCA strongly suggests that CMV is an essential factor in the NK cell activation, which progresses stepwise during leukemia and subsequent dasatinib treatment most likely by subclinical CMV reactivation. This study provides a rationale for the exploitation of CMV-associated NK cell activation for treatment of leukemias.

Inhibition by sphingosine of leukemic cell killing by human monocytes activated with interleukin-2: a possible role of protein kinase C.

Sphingosine and its analogs, which inhibit protein kinase C (PKC), are known to be potent inducers of apoptosis in tumor cells. However, we were concerned that sphingosine might also interfere with anti-tumor cells of the immune system. Therefore, we evaluated the effect of sphingosine on activation of human monocytes by interleukin-2 (IL-2) for killing of leukemic cells. Monocytes, purified by elutriation and adherence, were activated with IL-2 or interferon-gamma (IFN-gamma) in the presence or absence of sphingosine or another inhibitor for 18 h. Then the monocytes were washed and the culture medium was replaced with fresh medium to remove the sphingosine. HL- 60 and K562 leukemic cells were added to the monocyte cultures. Over the next 48 h, the cytotoxic activity of the monocytes towards the leukemic cells was assessed by means of an 111-indium-releasing assay. IL-2-activated monocytes lysed 48 +/- 3% of HL-60 cells and 44 +/- 3% of K562 cells. Sphingosine, dihydrosphingosine, N,N-dimethylsphingosine, and the PKC inhibitor H7 inhibited the activation of monocytes by IL-2, blocking cytotoxic activity against the leukemic cells by approximately 75%. These inhibitors were not toxic to monocytes at the concentrations used. In a PKC assay, sphingosine and H7 inhibited PKC activity in IL-2-treated monocytes. Thus, sphingosines, by inhibiting PKC activity, inhibited activation of monocytes by IL-2, which inhibited the killing of leukemic cells.

C2-ceramide and C6-ceramide inhibited priming for enhanced release of superoxide in monocytes, but had no effect on the killing of leukaemic cells by monocytes.

Ceramide acts as an intracellular second messenger in cellular signal transduction. We examined the effects of two cell-permeable ceramides, C2-ceramide and C6-ceramide, on human monocyte functions. After monocytes were primed with lipopolysaccharide (LPS) or interferon-gamma (IFN-gamma) for 18 hr in suspension culture, they produced a high amount of superoxide (O2-) when triggered by phorbol myristate acetate. C2- or C6-ceramide inhibited O2- release from monocytes primed with LPS (1 ng/ml) or IFN-gamma (100 U/ml), but did not affect unprimed monocytes. An analogue, C2-dihydroceramide, was inactive. C2-ceramide was most effective at 6 microM, and C6-ceramide at 60 microM. C2- or C6-ceramide at these concentrations was not toxic for monocytes, as assessed by trypan blue exclusion and by the 3-[4, 5-dimethylthiazol-2-y1]-2,5 diphenyl tetrazolium bromide (MTT) assay which measures the ability of live cells to produce formazan. C2-ceramide (20 microM) had no effect on the killing of leukaemic cells (HL-60 and K562 cells) by monocytes treated with IFN-gamma, LPS, or both for 18 hr, with killing assessed by an 111 Indium-releasing assay. C2-ceramide (20 microM) induced secretion of low amounts of tumour necrosis factor-alpha (TNF-alpha) and interleukin-1 beta (IL-1 beta) from the monocytes. But C2-ceramide did not alter the higher secretion of TNF-alpha or IL-1 beta from monocytes treated with IFN-gamma or LPS. Thus the cell-permeable ceramides acted like antagonists of LPS, rather than analogues of LPS, as has been proposed. The results here showed that the signal transduction pathway for O2- release by monocytes differed from that for the cytolysis of leukaemic cells, and confirmed that oxygen radicals are not involved in cytolysis.

Lysis of leukemic cells by human macrophages: inhibition by 4-(2-aminoethyl)-benzenesulfonyl fluoride (AEBSF), a serine protease inhibitor.

Proteases are known to be involved in regulation of macrophage activation and killing. We examined the effect of a serine protease inhibitor, 4-(2-aminoethyl)-benzenesulfonyl fluoride (AEBSF), on lysis of leukemic cells by human macrophages. Monocytes, isolated by Histopaque gradients and centrifugal elutriation, were cultured for 5 days in RPMI-1640 medium with 5% AB serum, and then activated with interferon-gamma (IFN-gamma; 100 U/mL) and lipopolysaccharide (LPS) (5 ng/mL), with or without AEBSF, for 2 days. On day 7, macrophages were washed, fresh medium without AEBSF added, and target cells added for 2 days. Lytic activity against two leukemic cell lines (K562 and HL-60) was assessed by an 111indium-releasing assay. Macrophages treated with IFN-gamma + LPS lysed K562 and HL-60 cells. AEBSF (50-150 microM) blocked the killing of these leukemic cells in a concentration-dependent manner. Other protease inhibitors were not effective. AEBSF was nontoxic at the concentrations used, and did not inhibit tumor necrosis factor-alpha (TNF-alpha) and interleukin-1 beta (IL-1 beta) secretion from the macrophages. The lytic activity against leukemic cells was inhibited by anti-TNF-alpha antibody, but not by anti-IL-1 beta, nor by superoxide dismutase or catalase. However, the leukemic cells were resistant to being killed by recombinant TNF-alpha alone in the absence of macrophages, indicating that TNF-alpha was required for killing, but that other factors that were inhibited by AEBSF were also required. Serum-free culture supernatant of activated macrophages had significant cytotoxic activity against leukemic cells. This cytotoxic activity was not altered by addition of AEBSF to the culture supernatant, suggesting that AEBSF affected macrophage activation, rather than inhibiting cytotoxic proteases secreted by the macrophages, or affecting the target cells themselves. Thus, a protease, which is susceptible to AEBSF, might be involved in the activation of macrophages, and might regulate the secretion of antitumor effector molecules other than TNF-alpha.

[Complete remission in acute myeloblastic leukemia (M0) after treatment with rhG-CSF].

A 57-year-old man was admitted because of fever and night sweat. The bone marrow was hypercellular with 86.4% blast cells. The diagnosis of AML (M0) was made, because the blast cells were negative for peroxidase stain and had CD13 and no lymphoid antigens in marker analysis. The patient was treated with BH-AC.TMP, BH-AC.MVP and low dose Ara-C without any hematological improvement, and even additional treatment with medium dose Ara-C resulted in 66.4% blast cells in the bone marrow. Subsequent administration of rhG-CSF (150 micrograms/day) by continuous intravenous infusion resulted in the decrease of the blast cells in the bone marrow to a level that was evaluated as complete remission. He remains in complete hematological remission at present. As shown in this case, rhG-CSF might be an effective agent for the treatment of AML, even if the mechanism of its effectiveness is unclear at present. Further clinical studies should will supply useful information to analyze the pathophysiology of AML.

Mechanism of leukemic cell lysis by activated human macrophages: leukemic cells can be lysed without direct contact.

We recently reported that human macrophages effectively destroyed leukemic cells. In this study, we investigated the mechanism of leukemic cell lysis by human macrophages. Human peripheral blood monocyte-derived macrophages were activated with interferon-gamma and lipopolysaccharide. Activated macrophages exhibited lytic activity against leukemic cells (K562 and HL-60 cells) by cocultivation. When macrophages and these leukemic cells were separated by a microporous membrane, activated macrophages did not show any lytic activity against these leukemic cells. However, activated macrophages interacting with leukemic cells under the microporous membrane exhibited lytic activity against leukemic cells that were placed on the microporous membrane. Different kinds of leukemic cells were also effective to induce such lytic activity in the macrophages, but normal lymphocytes could not. Culture supernatants of activated macrophages incubated with leukemic cells did not have cytolytic activity against leukemic cells. The leukemic cells used in this study were confirmed to be resistant to tumor necrosis factor (TNF), but the activated macrophage-mediated cytolytic activity was significantly inhibited by the anti-TNF antibody. These findings suggested that the contact between macrophages and leukemic cells triggered the secretion of lytic factor(s), and that TNF and other labile factor(s) co-operatively functioned to lyse leukemic cells.

Leukemic cell lysis by activated human macrophages: significance of membrane-associated tumor necrosis factor.

In this study, we analyzed the mechanism(s) of leukemic cell lysis by human macrophages. Peripheral blood monocyte-derived macrophages were activated with recombinant interferon-gamma and lipopolysaccharide and their lytic activity against two leukemic cell lines (K562 and HL-60 cells) was assessed by an 111In releasing assay. Activated macrophages lysed these leukemic cells, and the lytic activity against leukemic cells was almost completely inhibited by anti-tumor necrosis factor (TNF) antibody. The macrophage-lysate prepared from activated macrophages also exhibited significant lytic activity against leukemic cells; this lytic activity was inhibited by anti-TNF antibody. The leukemic cells that we used for the cytotoxicity assays were resistant to recombinant TNF. The culture supernatant of activated macrophages did not show any lytic activity. These findings suggest that cell-associated TNF plays a role in macrophage-mediated cytotoxicity against leukemic cells.