FOXM1 is an important cell cycle regulator and regulates cell proliferation. In addition, FOXM1 has been reported to contribute to oncogenesis in various cancers. However, it is not clearly understood how FOXM1 contributes to acute myeloid leukemia (AML) cell proliferation. In this study, we investigated the cellular and molecular function of FOXM1 in AML cells. The FOXM1 messenger RNA (mRNA) expressed in AML cell lines was predominantly the FOXM1B isoform, and its levels were significantly higher than in normal high aldehyde dehydrogenase activity (ALDH(hi)) cells. Reduction of FOXM1 expression in AML cells inhibited cell proliferation compared with control cells, through induction of G(2)/M cell cycle arrest, a decrease in the protein expression of Aurora kinase B, Survivin, Cyclin B1, S-phase kinase-associated protein 2 and Cdc25B and an increase in the protein expression of p21(Cip1) and p27(Kip1). FOXM1 messenger RNA (mRNA) was overexpressed in all 127 AML clinical specimens tested (n = 21, 56, 32 and 18 for M1, M2, M4 and M5 subtypes, respectively). Compared with normal ALDH(hi) cells, FOXM1 gene expression was 1.65- to 2.26-fold higher in AML cells. Moreover, the FOXM1 protein was more strongly expressed in AML-derived ALDH(hi) cells compared with normal ALDH(hi) cells. In addition, depletion of FOXM1 reduced colony formation of AML-derived ALDH(hi) cells due to inhibition of Cdc25B and Cyclin B1 expression. In summary, we found that FOXM1B mRNA is predominantly expressed in AML cells and that aberrant expression of FOXM1 induces AML cell proliferation through modulation of cell cycle progression. Thus, inhibition of FOXM1 expression represents an attractive target for AML therapy.
SummaryThe effect of CMC-544, a calicheamicin-conjugated anti-CD22 monoclonal antibody, was analysed in relation to CD22 and P-glycoprotein (P-gp) in B-cell chronic lymphocytic leukaemia (CLL) and non-Hodgkin lymphoma (NHL) in vitro. The cell lines used were CD22-positive parental Daudi and Raji, and their P-gp positive sublines, Daudi/MDR and Raji/MDR. Cells obtained from 19 patients with B-cell CLL or NHL were also used. The effect of CMC-544 was analysed by viable cell count, morphology, annexin-V staining, and cell cycle distribution. A dose-dependent, selective cytotoxic effect of CMC-544 was observed in cell lines that expressed CD22. CMC-544 was not effective on Daudi/MDR and Raji/MDR cells compared with their parental cells. The MDR modifiers, PSC833 and MS209, restored the cytotoxic effect of CMC-544 in P-gp-expressing sublines. In clinical samples, the cytotoxic effect of CMC-544 was inversely related to the amount of P-gp (P = 0AE003), and to intracellular rhodamine-123 accumulation (P < 0AE001). On the other hand, the effect positively correlated with the amount of CD22 (P = 0AE010). The effect of CMC-544 depends on the levels of CD22 and P-gp. Our findings will help to predict the clinical effectiveness of this drug on these B-cell malignancies, suggesting a beneficial effect with combined use of CMC-544 and MDR modifiers.
Bcr‐Abl activates various signaling pathways in chronic myelogenous leukemia (CML) cells. The proliferation of Bcr‐Abl transformed cells is promoted by c‐Myc through the activation of Akt, JAK2 and NF‐κB. However, the mechanism by which c‐Myc regulates CML cell proliferation is unclear. In our study, we investigated the role of Thanatos‐associated protein 11 (THAP11), which inhibits c‐Myc transcription, in CML cell lines and in hematopoietic progenitor cells derived from CML patients. The induction of THAP11 expression by Abl kinase inhibitors in CML cell lines and in CML‐derived hematopoietic progenitor cells resulted in the suppression of c‐Myc. In addition, over‐expression of THAP11 inhibited CML cell proliferation. In colony forming cells derived from CML‐aldehyde dehydrogenase (ALDH)hi/CD34+ cells, treatment with Abl kinase inhibitors and siRNA depletion of Bcr‐Abl induced THAP11 expression and reduced c‐Myc expression, resulting in inhibited colony formation. Moreover, overexpression of THAP11 significantly decreased the colony numbers, and also inhibited the expression of c‐myc target genes such as Cyclin D1, ODC and induced the expression of p21Cip1. The depletion of THAP11 inhibited JAK2 or STAT5 inactivation‐mediated c‐Myc reduction in ALDHhi/CD34+ CML cells. Thus, the induced THAP11 might be one of transcriptional regulators of c‐Myc expression in CML cell. Therefore, the induction of THAP11 has a potential possibility as a target for the inhibition of CML cell proliferation.
We studied the effect of CMC-544, the calicheamicin-conjugated anti-CD22 monoclonal antibody, used alone and in combination with rituximab, analyzing the quantitative alteration of target molecules, that is, CD20, CD22, CD55 and CD59, in Daudi and Raji cells as well as in cells obtained from patients with B-cell malignancies (BCM). Antibody inducing direct antiproliferative and apoptotic effect, complement-dependent cytotoxicity (CDC) and antibody-dependent cellular cytotoxicity (ADCC) were tested separately. In Daudi and Raji cells, the CDC effect of rituximab significantly increased within 12 h following incubation with CMC-544. The levels of CD22 and CD55 were significantly reduced (Po0.001 in both cells) after incubation with CMC-544, but CD20 level remained constant or increased for 12 h. Similar results were obtained in cells from 12 patients with BCM. The antiproliferative and apoptotic effect of CMC-544 were greater than that of rituximab. The ADCC of rituximab was not enhanced by CMC-544. Thus, the combination of CMC-544 and rituximab increased the in vitro cytotoxic effect in BCM cells, and sequential administration for 12 h proceeded by CMC-544 was more effective. The reduction of CD55 and the preservation of CD20 after incubation with CMC-544 support the rationale for the combined use of CMC-544 and rituximab.
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