Apoptosis in normal and neoplastic hematopoiesis

Effects of SET and SET-CAN on the differentiation of the human promonocytic cell line U937

Human SET encodes a nuclear phosphoprotein with a highly acidic carboxyl-terminus, forming a SET-CAN fusion gene in a patient with acute undifferentiated leukemia. SET is highly conserved between species and is ubiquitously expressed, suggesting a widespread biological role. Even though SET is involved in chromatin remodeling and transcriptional activation, its precise role in hematopoietic cells and the contribution of SET-CAN to leukemogenesis remains unknown. We determined the effect of tetracycline-regulatable expression of SET, a deletion mutant of SET, and SET-CAN on the human promonocytic cell line U937T. The expression of SET and SET-CAN inhibited proliferation of these cells. SET accomplishes this through the induction of the differentiation program, an effect that depends on the presence of its acidic domain. SET-CAN most likely inhibits growth by interfering with hCRM1, but it also partially blocks differentiation. Our results are the first demonstration of a potential role of SET in hematopoietic differentiation.

Tamoxifen (TMX)/Fas induced growth inhibition of human cholangiocarcinoma (HCC) by gamma interferon (IFN-gamma)

OBJECTIVES

To evaluate the response of human cholangoicarcinoma cells to TMX treatment through the Fas pathway by pretreatment with IFN-gamma.

SUMMARY BACKGROUND DATA

Cholangiocarcinoma remains one of the most difficult tumors to treat in clinical medicine. Currently, there are no effective chemotherapy treatments for this disease. Surgery offers the only opportunity for a cure, with the majority of patients failing to qualify for such treatment. This study seeks to evaluate a potential new modality for treatment of this disease.

METHODS

Human cholangiocarcinoma cells were treated with anti Fas mab and sorted to two populations (Fas-positive and Fas-negative) by FAC analysis. In vitro individual cell populations were pretreated with IFN-gamma 250 units/mL x 18hs. The treated cells assayed for caspase 3, 7, 8, Bak, and for apoptosis with Annexin V after treatment with or without TMX. In Vivo 2 x 106 5 SK-ChA-1 Fas-negative cells were injected into nude mice for development of tumor xenografts. Mice received either no treatment or intra tumor IFN-gamma and/or intra peritoneal TMX.

RESULTS

More than 90% (90% +/- 3.5%) of Fas-positive and 70% (71 +/- 2.3%) of Fas-negative cells underwent apoptosis after TMX treatment when pretreated with IFN-gamma. In contrast, TMX alone and IFN-gamma alone stimulated apoptosis by only 22% (22 +/- 3%) P <.00013, and 17% (17 +/- 2%) P <.0001 in Fas-ve cells respectively. In vivo human cholangiocarcinomas xenograft growth was significantly inhibited by a combination of TMX + IFN-gamma compared to controls P <.0007.

CONCLUSION

TMX exposure to human cholangiocarcinoma after pretreatment with IFN-gamma allows for induction of apoptosis in vitro and significant inhibition tumor xenograft growth. The combination of these two compounds may provide novel treatment regimen for cholangiocarcinoma.

IFN-gamma-dependent delay of in vivo tumor progression by Fas overexpression on murine renal cancer cells

The role of Fas in the regulation of solid tumor growth was investigated. Murine renal carcinoma (Renca) cells were constitutively resistant to Fas-mediated killing in vitro, but exhibited increased expression of Fas and sensitivity to Fas-mediated killing after exposure to IFN-gamma and TNF. Transfected Renca cells overexpressing Fas were efficiently killed in vitro upon exposure to anti-Fas Ab (Jo2). When Fas-overexpressing Renca cells were injected into syngenic BALB/c mice, there was a consistent and significant delay in tumor progression, reduced metastasis, and prolonged survival that was not observed for Renca cells that overexpressed a truncated nonfunctional Fas receptor. The delay of in vivo tumor growth induced by Fas overexpression was not observed in IFN-gamma-/- mice, indicating that IFN-gamma is required for the delay of in vivo tumor growth. However, there was a significant increase of infiltrated T cells and in vivo apoptosis in Fas-overexpressing Renca tumors, and Fas-overexpressing Renca cells were also efficiently killed in vitro by T cells. In addition, a strong therapeutic effect was observed on Fas-overexpressing tumor cells by in vivo administration of anti-Fas Ab, confirming that overexpressed Fas provides a functional target in vivo for Fas-specific ligands. Therefore, our findings demonstrate that Fas overexpression on solid tumor cells can delay tumor growth and provides a rationale for therapeutic manipulation of Fas expression as a means of inducing tumor regression in vivo.

Expression of Bcl-2 by human bone marrow mast cells and its overexpression in mast cell leukemia

Bcl-2 protein plays a major role in the prevention of programmed cell death of differentiating cells. In the present study, the expression of cytoplasmic bcl-2 by human Bone Marrow Mast Cells (BMMC) from both normal and pathological bone marrow samples was examined. A total of 35 subjects corresponding to 9 healthy volunteers, 8 cases of adult indolent systemic mast cell disease (SMCD), 4 cases of pediatric mastocytosis (PM), 11 cases of hematological malignancies (HM), 2 cases of reactive bone marrow, and 1 case of mast cell leukemia (MCL) were analyzed. The expression of bcl-2 was studied using quantitative three-color flow cytometry. We also studied the molecular configuration of the bcl-2 gene and other relatives by Southern blot and polymerase chain reaction (PCR) in the MCL case. Bcl-2 expression was detected in BMMC from all samples analyzed. No significant differences on the expression of bcl-2 were detected between BMMC from healthy subjects and patients with SMCD, PM, HM, and reactive bone marrow. By contrast, bcl-2 protein was overexpressed in BMMC from MCL patient without gene rearrangement. Our results show that bcl-2 protein was constitutively expressed by BMMC. BMMC from MCL display overexpression of bcl-2, which could not be related to molecular rearrangements involving the bcl-2 gene. The expression of this protein by mature MC may play a role in the prevention of MC apoptosis and thus help to explain the long survival of these cells. The overexpression of bcl-2 by BMMC in MCL may help to explain their resistance to chemotherapy-induced apoptosis.