Philadelphia chromosome-positive leukemia stem cells in acute lymphoblastic leukemia and tyrosine kinase inhibitor therapy

Leukemia stem cells(LSCs),which constitute a minority of the tumor bulk,are functionally defined on the basis of their ability to transfer leukemia into an immunodeficient recipient animal.The presence of LSCs has been demonstrated in acute lymphoblastic leukemia(ALL),of which ALL with Philadelphia chromosome-positive(Ph+).The use of imatinib,a tyrosine kinase inhibitor(TKI),as part of front-line treatment and in combination with cytotoxic agents,has greatly improved the proportions of complete response and molecular remission and the overall outcome in adults with newly diagnosed Ph+ ALL.New challenges have emerged with respect to induction of resistance to imatinib via Abelson tyrosine kinase mutations.An important recent addition to the arsenal against Ph+ leukemias in general was the development of novel TKIs,such as nilotinib and dasatinib.However,in vitro experiments have suggested that TKIs have an antiproliferative but not an antiapoptotic or cytotoxic effect on the most primitive ALL stem cells.None of the TKIs in clinical use target the LSC.Second generation TKI dasatinib has been shown to have a more profound effect on the stem cell compartment but the drug was still unable to kill the most primitive LSCs.Allogeneic stem cell transplantation(SCT) remains the only curative treatment available for these patients.Several mechanisms were proposed to explain the resistance of LSCs to TKIs in addition to mutations.Hence,TKIs may be used as a bridge to SCT rather than monotherapy or combination with standard chemotherapy.Better understanding the biology of Ph+ ALL will open new avenues for effective management.In this review,we highlight recent findings relating to the question of LSCs in Ph+ ALL.     

Salinomycin overcomes ABC transporter-mediated multidrug and apoptosis resistance in human leukemia stem cell-like KG-1a cells

Leukemia stem cells are known to exhibit multidrug resistance by expression of ATP-binding cassette (ABC) transporters which constitute transmembrane proteins capable of exporting a wide variety of chemotherapeutic drugs from the cytosol. We show here that human promyeloblastic leukemia KG-1a cells exposed to the histone deacetylase inhibitor phenylbutyrate resemble many characteristics of leukemia stem cells, including expression of functional ABC transporters such as P-glycoprotein, BCRP and MRP8. Consequently, KG-1a cells display resistance to the induction of apoptosis by various chemotherapeutic drugs. Resistance to apoptosis induction by chemotherapeutic drugs can be reversed by cyclosporine A, which effectively inhibits the activity of P-glycoprotein and BCRP, thus demonstrating ABC transporter-mediated drug resistance in KG-1a cells. However, KG-1a are highly sensitive to apoptosis induction by salinomycin, a polyether ionophore antibiotic that has recently been shown to kill human breast cancer stem cell-like cells and to induce apoptosis in human cancer cells displaying multiple mechanisms of drug and apoptosis resistance. Whereas KG-1a cells can be adapted to proliferate in the presence of apoptosis-inducing concentrations of bortezomib and doxorubicin, salinomycin does not permit long-term adaptation of the cells to apoptosis-inducing concentrations. Thus, salinomycin should be regarded as a novel and effective agent for the elimination of leukemia stem cells and other tumor cells exhibiting ABC transporter-mediated multidrug resistance.     

E35 ablates acute leukemia stem and progenitor cells in vitro and in vivo

Leukemia stem cells (LSCs) have critical functions in acute leukemia (AL) pathogenesis, participating in its initiation and relapse. Thus, identifying new molecules to eradicate LSCs represents a high priority for AL management. This work identified E35, a novel Emodin derivative, which strongly inhibited growth and enhanced apoptosis of AL stem cell lines, and primary stem and progenitor cells from AL cases, while sparing normal hematopoietic cells. Furthermore, functional assays in cultured cells and animals suggested that E35 preferentially ablated primitive leukemia cell populations without impairing their normal counterparts. Moreover, molecular studies showed that E35 remarkably downregulated drug-resistant gene and dramatically inhibited the Akt/mammalian target of rapamycin signaling pathway. Notably, the in vivo anti-LSC activity of E35 was further confirmed in murine xenotransplantation models. Collectively, these findings indicate E35 constitutes a novel therapeutic candidate for AL, potentially targeting leukemia stem and progenitor cells.     

Significance of mitotic spindle checkpoint genes in leukemia

Leukemia is a clonal proliferative disorder of a multipotent hematopoietic stem cell that leads to abnormal cell growth and/or differentiation. The hallmark of the disease is the presence of oncogene expression in bone marrow or peripheral blood resulting from chromosome translocations. The development of leukemia and the progression of the disease are multistage processes implicated in a series of molecular changes preceeded chromosomal instability and aneuploidy. The most likely of the above-mentioned changes include the following: the appearance of additional chromosome translocations, the activation of other oncogenes not expressed previously, the loss of tumor suppressor genes, abnormal centrosome duplication, and the dysfunction of genes that coordinate accurate chromosome alignment and chromosome segregation during mitosis. The last two molecular events controlled by mitotic spindle checkpoint genes play a role in leukemogenesis and are probably involved in apoptosis.     

外泌体在白血病中的重要调控作用

目前,白血病复发是患者死亡的主要原因之一。肿瘤细胞和微环境的相互作用,以及隐匿在骨髓中的肿瘤干细胞,促进了白血病的复发和向淋巴组织的转移,因此白血病的治疗、转移和复发问题受到广泛关注。外泌体是由绝大多数细胞分泌的双层脂质膜囊泡,可以调控细胞间的交流和信息传递。在白血病细胞、基质细胞和内皮细胞之间的相互联系中都涉及到外泌体,白血病细胞来源的外泌体存在于白血病患者的血浆中,能把其携带的白血病相关抗原及微小RNA呈递给靶细胞,促进白血病肿瘤细胞的增殖,有助于肿瘤细胞实现免疫逃避,保护白血病细胞抵抗化疗药物导致的细胞毒性作用,促进血管生成及肿瘤细胞的迁移。因此,外泌体与白血病的转移、治疗及预后密切相关,可以用来检测和监测白血病的进展。本文综述了外泌体的来源、形成与分泌机制,以及外泌体在白血病发生前、发展中、预后和免疫治疗中所扮演的重要角色。     

Granulocyte differentiation by Friend leukemia cells.

Friend leukemia cells growing in suspension culture are thought to represent a population of primitive erythroid cells which have undergone malignant transformation. We have found that when growing in vivo or in plasma clots in vitro, these suspension culture cells can exhibit morphologic and enzymatic properties which are characteristic of primitive granulocytic cells. The microenvironment in which the tumor cells grow plays a major role in determining the direction of differentiation of these leukemia cells. Hence it appears likely that the Friend cell is in fact a neoplastic pluripotent hematopoietic stem cell.     

Syngeneic leukemia models using lentiviral transgenics

Animal models are necessary to study cancer and develop treatments. After decades of intensive research, effective treatments are available for only a few types of leukemia, while others are currently incurable. Our goal was to generate novel leukemia models in immunocompetent mice. We had achieved abilities for overexpression of multiple driving oncogenes simultaneously in normal primary cells, which can be transplanted and followed in vivo. Our experiments demonstrated the induction of primary malignant growth. Leukemia lines that model various types of leukemia, such as acute myeloid leukemia (AML) or chronic lymphocytic leukemia (CLL), were passaged robustly in congenic wild-type immunocompetent mice. These novel leukemia lines, which may complement previous models, offer the flexibility to generate tailored models of defined oncogenes of interest. The characterization of our leukemia models in immunocompetent animals can uncover the mechanisms of malignancy progression and offer a unique opportunity to stringently test anti-cancer chemotherapies.Subject terms: Cancer models, Haematopoietic stem cells, Leukaemia     

Hedgehog pathway activation in chronic myeloid leukemia: A promise for a novel combination therapeutic approach?

Chronic Myeloid Leukemia (CML) is a hematopoietic stem cell malignancy that is driven by the oncogenic BCR-ABL fusion protein, and for which treatment with ABL tyrosine kinase inhibitors (TKI) has yielded great success. While this is the case, BCR-ABL leukemic stem cells can persist despite TKI therapy, and efforts have intensified towards determining the molecular pathways that are critical for the maintenance of such cells. Recent studies indicate that aberrant Hedgehog (Hh) signaling plays a crucial role in the survival of the leukemic stem cell population. The Hh pathway displays crucial roles during embryonic development, tissue regeneration and repair in adults. Several mechanisms that lead to the aberrant activation of the Hh pathway have been identified in various cancers. Here we review in detail the discovery that Hh signaling governs the maintenance of the critical leukemia initiating cells or leukemic stem cells (LSCs) in BCR-ABL-induced CML as well as discuss investigations on the role of Hh signaling in normal hematopoeisis. As inhibitors that directly target the positive Hh signal transducer Smoothened (SMO) have entered clinical trials, these findings offer a unique opportunity to potentially target the LSC population that is not eliminated with ABL tyrosine kinase inhibition therapy in CML.     

Targeted therapy: The new lease on life for acute promyelocytic leukemia, and beyond

Leukemia, a group of hematological malignancies characterized by abnormal proliferation, decreased apoptosis, and blocked differentiation of hematopoietic stem/progenitor cells, is a disease involving dynamic change in the genome. Chromosomal translocation and point mutation are the major mechanisms in leukemia, which lead to production of oncogenes with dominant gain of function and tumor suppressor genes with recessive loss of function. Targeted therapy refers to treatment strategies perturbing the molecules critical for leukemia pathogenesis. The t(15;17) which generates PML-RARα, t(8;21) that produces AML1-ETO, and t(9;22) which generates BCR-ABL are the three most frequently seen chromosomal translocations in myeloid leukemia. The past two to three decades have witnessed tremendous success in development of targeted therapies for acute and chronic myeloid leukemia caused by the three fusion proteins. Here, we review the therapeutic efficacies and the mechanisms of action of targeted therapies for myeloid leukemia and show how this strategy significantly improve the clinical outcome of patients and even turn acute promyelocytic leukemia from highly fatal to highly curable.     

Characterization, chromosomal assignment, and role of LIFR in early embryogenesis and stem cell establishment of rabbits

Leukemia inhibitory factor (LIF) is a multifunctional cytokine with an important role during early embryonic development, implantation, and as an inhibitor of murine embryonic stem cell differentiation. It exerts its effects by binding to the leukemia inhibitory factor receptor, a heterodimer of two transmembrane proteins, the specific leukemia inhibitory factor receptor subunit, and the common gp130. A partial cDNA clone coding for the membrane-bound form of the specific rabbit leukemia inhibitory factor receptor was isolated from the genital ridge of 13.5 days postcoitum fetus. Fluorescent in situ hybridization analysis revealed that the rabbit leukemia inhibitory factor receptor gene is located on chromosome OCU11p11.1. It has been shown that the membrane-bound rabbit leukemia inhibitory factor receptor mRNA is expressed during embryo implantation but not at earlier developmental stages. Rabbit embryonic stem cell-like line establishment is improved in the presence of LIF, and those cells express both leukemia inhibitory factor and its receptor. The withdrawal of leukemia inhibitory factor results the differentiation of embryonic stem cell-like cells to beating myocardial-like cells. Our findings suggest that the self-renewal mechanism is similar in mouse and rabbit embryonic stem cells, and expands our knowledge on the role of the LIF-LIFR signal pathway in early rabbit embryogenesis and rabbit embryonic stem cell establishment.     

Abrogation of radiation leukemia virus-induced lymphomagenesis by antisera to thymotropic but not to ecotropic or dual-tropic viruses.

Leukemia induction by culture-grown thymotropic radiation leukemia virus or by tumor-derived virus present in cell-free tumor extracts was abrogated by incubation of either virus with anti-thymotropoc virus serum, but not by antiserum raised against ecotropic or dual-tropic (mink cell focus-inducing type) viruses that were isolated from radiation leukemia virus-induced thymic leukemias. Thus, virus similar or identical to the cultured thymotropic leukemogenic species may also be the major biologically active principle in tumor-derived extracts, even though the latter also contain viruses of the dual-tropic, mink cell focus-inducing type class.     

Hypoxia selects bortezomib-resistant stem cells of chronic myeloid leukemia

We previously demonstrated that severe hypoxia inhibits growth of Chronic Myeloid Leukemia (CML) cells and selects stem cells where BCR/Abl(protein) is suppressed, although mRNA is not, so that hypoxia-selected stem cells, while remaining leukemic, are independent of BCR/Abl signaling and thereby refractory to Imatinib-mesylate. The main target of this study was to address the effects of the proteasome inhibitor Bortezomib (BZ) on the maintenance of stem or progenitor cells in hypoxic primary cultures (LC1), by determining the capacity of LC1 cells to repopulate normoxic secondary cultures (LC2) and the kinetics of this repopulation. Unselected K562 cells from day-2 hypoxic LC1 repopulated LC2 with rapid, progenitor-type kinetics; this repopulation was suppressed by BZ addition to LC1 at time 0, but completely resistant to day-1 BZ, indicating that progenitors require some time to adapt to stand hypoxia. K562 cells selected in hypoxic day-7 LC1 repopulated LC2 with stem-type kinetics, which was largely resistant to BZ added at either time 0 or day 1, indicating that hypoxia-selectable stem cells are BZ-resistant per se, i.e. before their selection. Furthermore, these cells were completely resistant to day-6 BZ, i.e. after selection. On the other hand, hypoxia-selected stem cells from CD34-positive cells of blast-crisis CML patients appeared completely resistant to either time-0 or day-1 BZ. To exploit in vitro the capacity of CML cells to adapt to hypoxia enabled to detect a subset of BZ-resistant leukemia stem cells, a finding of particular relevance in light of the fact that our experimental system mimics the physiologically hypoxic environment of bone marrow niches where leukemia stem cells most likely home and sustain minimal residual disease in vivo. This suggests the use of BZ as an enhanced strategy to control CML. in particular to prevent relapse of disease, to be considered with caution and to need further deepening.     

Design,synthesis and evaluation of anti-CD123 antibody drug conjugates

Leukemia stem cells (LSCs) account for the development of drug resistance and increased recurrence rate in acute myeloid leukemia (AML) patients. Targeted drug delivery to leukemia stem cells remains a major challenge in AML chemotherapy. Overexpressed interleukin-3 receptor alpha chain, CD123, on the surface of leukemia stem cells was reported to be a potential target in AML treatment. Here, we designed and developed an antibody drug conjugate (CD123-CPT) by integrating anti-CD123 antibody with a chemotherapeutic agent, Camptothecin (CPT), via a disulfide linker. The linker is biodegradable in the presence of Glutathione (GSH, an endogenous component in cells), which leads to release of CPT. Anti-CD123 antibody conjugates showed significant higher cellular uptake in CD123-overexpressed tumor cells. More importantly, CD123-CPT demonstrated potent inhibitory effects on CD123-overexpressed tumor cells. Consequently, these results provide a promising targeted chemotherapeutical strategy for AML treatment.     

Definitive hematopoiesis requires the mixed-lineage leukemia gene

The Mixed-Lineage Leukemia (MLL) gene encodes a Trithorax-related chromatin-modifying protooncogene that positively regulates Hox genes. In addition to their well-characterized roles in axial patterning, Trithorax and Polycomb family proteins perform less-understood functions in vertebrate hematopoiesis. To define the role of MLL in the development of the hematopoietic system, we examined the potential of cells lacking MLL. Mll-deficient cells could not develop into lymphocytes in adult RAG-2 chimeric animals. Similarly, in vitro differentiation of B cells required MLL. In chimeric embryos, Mll-deficient cells failed to contribute to fetal liver hematopoietic stem cell/progenitor populations. Moreover, we show that aorta-gonad-mesonephros (AGM) cells from Mll-deficient embryos lacked hematopoietic stem cell (HSC) activity despite their ability to generate hematopoietic progeny in vitro. These results demonstrate an intrinsic requirement for MLL in definitive hematopoiesis, where it is essential for the generation of HSCs in the embryo.     

Identification of leukemia stem cells in acute myeloid leukemia and their clinical relevance

Acute myeloid leukemia (AML) is considered to be a disease of stem cells. A rare defective stem cell population is purported to drive tumor growth. Similarly to their normal counterparts, leukemic stem cells (LSC) divide extreme slowly. This may explain the ineffectiveness of conventional chemotherapy in combatting this disease. Novel treatment strategies aimed at disrupting the binding of LSC to stem cell niches within the bone marrow might render the LSC vulnerable to chemotherapy and thus improving treatment outcome. This review focuses on the detection of LSC, our current knowledge about their cellular and molecular biology, and LSC interaction with the niche. Finally, we discuss the clinical relevance of LSC and prospective targeted treatment strategies for patients with AML.     

Identification and characterization of a soluble suppressor factor(s) in the serum of AKR mice bearing lymphocytic leukemia

Leukemia in AKR mice was found to be associated with the presence of a serum factor(s) termed AKR leukemic suppressor factor (AKR-LSF). Suppression was quantitated by measuring the inhibition of PHA-stimulated [³H]thymidine incorporation by normal AKR spleen cells at various dilutions of leukemic mouse serum (LMS). AKR-LSF activity was expressed as units per milliliter, which is the reciprocal of the LMS dilution that inhibited [³H]thymidine uptake by 50% with respect to fetal calf serum control cultures. The amount of activity in the serum directly correlated to the rate of tumor cell growth. Mice receiving 10⁷ BW5147 transplanted leukemia cells had 130 ± 12 units of AKR-LSF activity/ml of serum compared to 40 ± 8 units/ ml for mice with spontaneous leukemia. Normal mouse serum contained 33 ± 11 units/ml. The leukemic serum exhibited no strain specificity in either phytohemagglutinin or lipopolysaccharide assays, but was found to be twofold more inhibitory against mouse spleen cells than that against rat spleen cells. Human lymphocyte blastogenesis was not inhibited by the leukemic serum. LMS did not inhibit the growth of L929 fibroblasts or murine tumor cells in vitro. Further work is necessary to determine what role the suppressor factor may play in the regulation of antitumor cell immunity.     

Distribution and comparison of receptors for leukemia inhibitory factor on murine hemopoietic and hepatic cells

Leukemia inhibitory factor (LIF) is a glycoprotein that induces the differentiation of the monocytic leukemia cell line M1 but suppresses the differentiation of totipotent embryonic stem cells. In an attempt to define the normal cellular targets for LIF, the distribution of LIF receptors within hemopoietic and hepatic tissue was analyzed by binding cells with radioiodinated LIF (¹²⁵I-LIF) and subsequently carrying out autoradiography. Autoradiography demonstrated that in each he-mopoietic tissue examined cells of monocyte/macrophage lineage were the primary cell type labeled with ¹²⁵I-LIF. Moreover, both fetal and adult parenchy-mal hepatocytes displayed higher levels of labeling than either monocytes or macrophages. The number of receptors per positive cell varied from 150 for bone marrow monocytes to 2,000 for adult hepatocytes. In each case, however, binding was of high affinity, with an apparent K_D of 34–100 pM, and binding was specific, since labeling was competed for by unlabeled LIF but not a range of other structurally unrelated growth and differentiation factors. It is suggested that LIF may play a role in regulating macrophage function and hepatic acute phase protein synthesis in response to infection.     

CD9 correlates with cancer stem cell potentials in human B-acute lymphoblastic leukemia cells

Cancer stem cell (CSC) theory suggests that only a small subpopulation of cells having stem cell-like potentials can initiate tumor development. While recent data on acute lymphoblastic leukemia (ALL) are conflicting, some studies have demonstrated the existence of such cells following CD34-targeted isolation of primary samples. Although CD34 is a useful marker for the isolation of CSCs in leukemias, the identification of other specific markers besides CD34 has been relatively unsuccessful. To identify new markers, we first performed extensive analysis of surface markers on several B-ALL cell lines. Our data demonstrated that every B-ALL cell line tested did not express CD34 but certain lines contained cell populations with marked heterogeneity in marker expression. Moreover, the CD9⁺ cell population possessed stem cell characteristics within the clone, as demonstrated by in vitro and transplantation experiments. These results suggest that CD9 is a useful positive-selection marker for the identification of CSCs in B-ALL.     

p53 restoration kills primitive leukemia cells in vivo and increases survival of leukemic mice

Loss of p53 function is a common feature of human cancers and it is required for differentiated tumor cell maintenance; however, it is not known whether sustained inactivation of the p53 pathway is needed for cancer stem cell persistence. Chronic myeloid leukemia (CML) is caused by a chromosome translocation that generates the BCRABL oncogene encoding a constitutively active protein tyrosine kinase. The disease originates in a hematopoietic stem cell and is maintained by leukemic stem cells (LSCs). Treatment with specific tyrosine kinase inhibitors does not eliminate LSCs because they do not depend on the oncogene for survival. We have combined a switchable p53 knock-in mouse model, p53^KI/KI, with the well-characterized Sca1-BCRABLp210 CML transgenic model, to show that transient restoration of p53 slows disease progression and significantly extends the survival of leukemic animals, being the mechanism responsible for this effect, apoptotic death of primitive leukemia cells. In agreement with these in vivo findings, in vitro assays show that restoring p53 reduces hematopoietic colony formation by cells of leukemic animals. These results suggest that reestablishing p53 function may be a therapeutic strategy for the eradication of leukemic stem cells and to prevent disease progression.