Acute myeloid leukemia (AML) is a heterogeneous leukemia characterized by the blockage of myeloid differentiation at different stages, which define distinct AML subtypes. We have recently reported that the ligation of CD44 with 2 activating monoclonal antibodies (mAbs), A3D8 and H90, triggers terminal differentiation of leukemic blasts in AML-M1/2 to AML-M5 subtypes, which are the most frequent ones. However, fresh AML blasts have short in vitro lifespans. Therefore, to find relevant in vitro cellular models for further studying the mechanisms involved in CD44-induced differentiation, we investigated whether CD44 ligation with A3D8 and H90 mAbs can induce terminal differentiation of THP-1, NB4, and HL60 cells, each interesting models of AML-M5 (monoblastic subtype), AML-M3 (promyelocytic subtype), and AML-M2 (myeloblastic subtype), respectively. We also study whether CD44 ligation induces a loss of proliferative capacity, an important feature of late-stage myeloid differentiation. In the second part of our study, we investigated whether A3D8 and H90 anti-CD44 mAbs can induce the differentiation and inhibit the proliferation of KG1a cells, which are very immature AML-M0 blasts. Using functional, antigenic, and cytologic criteria, we presently show that A3D8 and/or H90 induce terminal differentiation of THP-1, HL60, and NB4 cell lines and strongly inhibit their proliferation. Interestingly, cell-specific effects of H90 and A3D8 are observed. We also observe that incubation with A3D8 for 3 to 6 days induces an apoptotic cell death that is moderate in the case of THP-1 and HL60 cells and massive in the case of NB4 cells.
Acute myeloid leukemia (AML) is sustained by the extensive proliferation of leukemic stem and progenitor cells, which give rise to the population of leukemic blasts with defective differentiation and low proliferative capacity. We have recently shown that ligation of CD44, a cell surface molecule present on AML cells, with specific monoclonal antibodies (mAbs) inhibits their proliferation. However, its mechanism has not been investigated yet. Here, using the NB4 cell line as a model of proliferating human AML cells, and the A3D8 mAb to ligate CD44, we show for the first time that CD44 ligation stabilizes the cyclin-dependent kinase inhibitor p27 Kip1 (p27) protein, resulting in increased association with cyclin E/Cdk2 complexes and inhibition of their kinase activity. Moreover, using a p27 antisense vector, we provide direct evidence that p27 is the main mediator of cell growth arrest by CD44. CD44 ligation also leads to p27 accumulation in THP-1, KG1a, and HL60 cell lines and in primary leukemic cells, suggesting that this process is general in AML. Taken together, our present results suggest that CD44 is a new and efficient means to increase the expression of p27 in AML cells. Considering that elevated expression of p27 is a factor of good prognosis in AML, these results provide a new basis for developing CD44-targeted therapy in AML. IntroductionAcute myeloid leukemia (AML) is characterized by the excess production of leukemic blasts arrested at various stages of granulocytic and monocytic differentiation. These stages define distinct AML subtypes (AML0 to AML5). 1 Most leukemic blasts have low proliferative capacity, and the leukemic clone is maintained by the extensive proliferation of subpopulations of leukemic stem and progenitor cells. 2 Therefore, elimination of proliferating leukemic cells is central to effectively cure AML patients. Because chemotherapy rarely eradicates the leukemic clone, efforts are being made to find innovative therapies, including ways for inhibiting the proliferation of AML cells (which is compatible with associated chemotherapy). 3,4 CD44 is a transmembrane glycoprotein expressed on the surface of normal and leukemic myeloid cells. [5][6][7][8] It mediates the adhesion of normal progenitors and of leukemic cells to hyaluronan, 9-11 a glycosaminoglycan component of the extracellular matrix. 12 CD44 has an important role in normal myelopoiesis, because anti-CD44 antibodies profoundly alter in vitro myelopoiesis in long-term bone marrow cultures (some antibodies fully abrogate it [13][14][15] and others enhance it [15][16][17] ). In the context of AML, our own experiments have shown that it is possible to reverse differentiation blockage in AML cells through CD44 ligation with specific antibodies. 18,19 This reversion was obtained in primary blasts from distinct AML subtypes, indicating new possibilities for the development of CD44-targeted differentiation therapy in AML. 18 It was also obtained in cell lines that are models of AML3 (NB4, promyelocytic), AML5 (THP-1, monoblastic)...
We have recently reported that ligation of the CD44 cell surface antigen with A3D8 monoclonal antibody (mAb) triggers incomplete differentiation and apoptosis of the acute promyelocytic leukemia (APL)-derived NB4 cells. The present study characterizes the mechanisms underlying the apoptotic effect of A3D8 in NB4 cells. We show that A3D8 induces activation of both initiator caspase-8 and -9 and effector caspase-3 and -7 but only inhibition of caspase-3/7 and caspase-8 reduces A3D8-induced apoptosis. Moreover, A3D8 induces mitochondrial alterations (decrease in mitochondrial membrane potential DW m and cytochrome c release), which are reduced by caspase-8 inhibitor, suggesting that caspase-8 is primarily involved in A3D8-induced apoptosis of NB4 cells. However, the apoptotic process is independent of TNF-family death receptor signalling. Interestingly, the general serine protease inhibitor 4-(2-aminoethyl)-benzenesulfonyl fluoride (AEBSF) decreases A3D8-induced apoptosis and when combined with general caspase inhibitor displays an additive effect resulting in complete prevention of apoptosis. These results suggest that both caspase-dependent and serine protease-dependent pathways contribute to A3D8-induced apoptosis. Finally, A3D8 induces apoptosis in all-trans-retinoic acid-resistant NB4-derived cells and in APL primary blasts, characterizing the A3D8 anti-CD44 mAb as a novel class of apoptosis-inducing agent in APL.
Acute myeloid leukemia (AML) is a clonal malignant disease characterized by an increasing number of immature myeloid cells arrested at various stages of granulocytic and monocytic differentiation. The stage of the blockage defines distinct AML subtypes (AML1 to AML5 are the most frequent ones). There is increasing evidence that the malignant clone is maintained by rare AML stem cells endowed with self-renewal capacity, which through extensive proliferation coupled to partial differentiation, generate leukemic progenitors and blasts, of which the vast majority have limited proliferative capacity. Contrarily to chemotherapy alone, which is still unable to cure most AML patients, the differentiation therapy, which consists in releasing the differentiation blockage of leukemic blasts, has succeeded, when it is combined with chemotherapy, to greatly improve the survival of AML3 patients, using retinoic acid as differentiating agent. However, this molecule is ineffective in other AML subtypes, which are the most frequent. We have shown that specific monoclonal antibodies (mAbs, H90 and A3D8) directed to the CD44 cell surface antigen, that is strongly expressed on human AML blasts, are capable of triggering terminal differentiation of leukemic blasts in AML1 to AML5 subtypes. These results have raised the perspective of developing a CD44-targeted differentiation therapy in most AML cases. Interestingly, these anti-CD44 mAbs can also induce the differentiation of AML cell lines, inhibit their proliferation and, in some cases, induce their apoptotic death. These results suggest that H90 and/or A3D8 mAbs may be capable to inhibit the proliferation of leukemic progenitors, to promote the differentiation of the leukemic stem cells at the expense of their self-renewal, and, perhaps, to induce their apoptotic death, thereby contributing to decrease the size of the leukemic clone. The challenges of an anti-CD44 based differentiation therapy in AML, and its importance in relation to the new other therapies developed in this malignancy, are discussed in this review.
We have recently reported that ligation of the CD44 cell surface antigen with A3D8 monoclonal antibody (mAb) triggers incomplete differentiation and apoptosis of the acute promyelocytic leukemia (APL)-derived NB4 cells. The present study characterizes the mechanisms underlying the apoptotic effect of A3D8 in NB4 cells. We show that A3D8 induces activation of both initiator caspase -8 and -9, and effector caspase-3 and -7 but only inhibition of caspase-3/7 and caspase-8 reduces A3D8-induced apoptosis. Moreover, A3D8 induces mitochondrial alterations (decrease in mitochondrial membrane potential ΔΨm and cytochrome c release) which are reduced by caspase-8 inhibitor suggesting that caspase-8 is primarily involved in A3D8-induced apoptosis of NB4 cells. However, the apoptotic process is independent of TNF-family death receptor signalling. Interestingly, the general serine protease inhibitor 4-(2-aminoethyl)-benzenesulfonyl fluoride (AEBSF) decreases A3D8-induced apoptosis and when combined with general caspase inhibitor displays an additive effect resulting in complete prevention of apoptosis. These results suggest that both caspase-dependent and serine protease-dependent pathways contribute to A3D8-induced apoptosis. Finally, A3D8 induces apoptosis in ATRA-resistant NB4-derived cells and in APL primary blasts, characterizing the A3D8 anti-CD44 mAb as a novel class of apoptosis-inducing agent in APL.
The CD44 surface antigen is highly expressed on AML cells. We previously reported that its ligation with specific monoclonal antibodies (mAbs) triggers terminal differentiation of leukemic blasts in all AML subtypes. This raised the perspective of developing a CD44-targeted therapy that would be efficient in all AML subtypes, including the monoblastic one (AML-M5) in which, in the absence of specific genetic abnormalities, no targeted therapy is being developed. Here we investigated the molecular mechanism responsible for the CD44-induced differentiation in primary AML-M5 blast samples (n=13). Firstly, by using cDNA arrays, we show that CD44 ligation:activates a burst of cytokine and chemokine genes, through the p38MAPK pathway, indicating that normal CD44 pathways are functional in AML-M5 blasts; andmodulates the gene expression of enzymes, surface proteins and transcription factors as in normal monopoiesis.Secondly, by using functional inhibitors, we demonstrate that the differentiation of CD44-ligated AML-M5 blasts is mediated by IL-1b, GM-CSF and IL-8. These proteins act locally, through an autocrine/paracrine pathway, suggesting that most of the drawbacks often provoked by their systemic injection should be very attenuated. Together, these results provide new support for the development of a CD44-targeted differentiation therapy in acute monoblastic leukemia.
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