Persistence of leukemic stem cells (LSC) after chemotherapy is thought to be responsible for relapse and prevents the curative treatment of acute myeloid leukemia (AML) patients. LSC and normal hematopoietic stem cells (HSC) share many characteristics and co-exist in the bone marrow of AML patients. For the development of successful LSC-targeted therapy, enabling eradication of LSC while sparing HSC, the identification of differences between LSC and HSC residing within the AML bone marrow is crucial. For identification of these LSC targets, as well as for AML LSC characterization, discrimination between LSC and HSC within the AML bone marrow is imperative. Here we show that normal CD34+CD38– HSC present in AML bone marrow, identified by their lack of aberrant immunophenotypic and molecular marker expression and low scatter properties, are a distinct sub-population of cells with high ALDH activity (ALDHbright). The ALDHbright compartment contains, besides normal HSC, more differentiated, normal CD34+CD38+ progenitors. Furthermore, we show that in CD34-negative AML, containing solely normal CD34+ cells, LSC are CD34– and ALDHlow. In CD34-positive AML, LSC are also ALDHlow but can be either CD34+ or CD34–. In conclusion, although malignant AML blasts have varying ALDH activity, a common feature of all AML cases is that LSC have lower ALDH activity than the CD34+CD38– HSC that co-exist with these LSC in the AML bone marrow. Our findings form the basis for combined functionally and immunophenotypically based identification and purification of LSC and HSC within the AML bone marrow, aiming at development of highly specific anti-LSC therapy.
Only a minority of cells, the leukemic stem cells (LSC), within AML are responsible for tumor growth and maintenance. Many patients experience relapse after therapy which originates from outgrowth of therapy resistant LSC. Therefore, eradication of LSC is necessary to cure AML. Both the normal hematopoietic stem cells (HSC) and LSC co-exist in the bone marrow (BM) of AML patients and success of anti-LSC strategies relies on specific elimination of LSC while sparing HSC. LSC are contained within the CD34+CD38-, the side population (SP) and the high aldehyde dehydrogenase (ALDH) activity compartments. ALDH is a detoxifying enzyme responsible for oxidation of intracellular aldehydes and high ALDH activity results in resistance to alkylating agents such as cyclophosphamide. It has been shown that ALDH is highly expressed in both normal progenitor and stem cells and in AML blasts. In view of applicability of LSC specific therapies the detoxification by ALDH is clinically very important. A difference in ALDH activity between HSC and LSC might be used to preferentially kill LSC while sparing HSC. To establish ALDH activity differences between HSC and LSC it should be possible to discriminate between them. We have shown that LSC can be identified and discriminated from HSC using stem cell-associated cell surface markers, such as CLL-1, lineage markers (CD7, CD19, CD56) and recently CD34/CD45 expression and cell size characteristics (Terwijn, Blood 111: 487, 2008). This offers the opportunity to identify co-existing LSC and HSC in the AML BM. We now show that, although malignant AML blasts have varying ALDH activity, a common feature of all AML cases is that HSC that co-exist with LSC in BM of AML patients have a higher ALDH activity as compared to their malignant counterparts. We have analyzed ALDH activity in HSC and LSC, both present in the BM from 18 AML patients. In nine BM AML samples, defined as CD34negative (<1%CD34+ blasts), the CD34+ compartment contained only normal CD34+CD38− HSC. The ALDH activity in these CD34+ HSC, is a factor 4,4 (range 1,7–18,9) higher than in LSC. In nine BM AML samples, defined as CD34positive AML, the CD34+CD38- HSC have a 7,7 fold (range 1,73–29,2 fold) higher ALDH activity as compared to putative LSC. In both CD34-positive and CD34-negative AML, we confirmed the identity of HSC and LSC by screening for molecular aberrancies present in AML blasts. The level of the ALDH activity of HSC within the AML BM is similar to that of HSC in NBM of healthy donors. In conclusion, high ALDH activity is an unique marker of normal HSC within the AML BM (irrespective of AML phenotype) at diagnosis. Consequently, AML patients with high ALDH activity in HSC might benefit from treatment with agents that will be converted by ALDH enzymes, such as cyclophosphamide, whereby the difference between the activity in LSC and HSC will define the therapeutic window. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 102nd Annual Meeting of the American Association for Cancer Research; 2011 Apr 2-6; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2011;71(8 Suppl):Abstract nr LB-45. doi:10.1158/1538-7445.AM2011-LB-45
4035 Poster Board III-971 Only a minority of cells, the leukemic stem cells (LSCs), within AML are responsible for tumor growth and maintenance. Many patients experience a relapse after therapy which is thought to originate from the outgrowth of therapy resistant LSC. Therefore, eradication of the LSCs is likely necessary to cure AML. Both the normal hematopoietic stem cells (HSCs) and LSCs co-exist in the bone marrow (BM) of leukemia patients and therefore success of an anti-stem-cell strategy relies on specific induction of LSC death while sparing the normal HSC. In AML, apart from the CD34+CD38- and the side population (SP) compartment, the high ALDH activity compartment contains the LSCs. The SP and ALDH defined compartments may include both CD34+ and CD34- HSCs and LSCs. ALDH is a detoxifying enzyme responsible for the oxidation of intracellular aldehydes and high ALDH activity results in resistance to alkylating agents such as the active derivatives of cyclophosphamide. Recent data has shown that ALDH is highly expressed in both normal progenitor and stem cells and in AML blast cells. In view of the applicability of LSC specific therapies the detoxification by ALDH might be of importance. Therefore, a difference in ALDH activity between the normal HSC and the malignant LSC might be used to preferentially kill the LSC and spare the HSC. We have previously shown that CD34+CD38- and SP LSCs can be identified and discriminated from HSCs using stem cell-associated cell surface markers, including C-type lectin-like molecules (CLL-1), lineage markers, such as CD7, CD19, and CD56 and recently cell size characteristics as measured by flow cytometry (Terwijn, Blood 111: 487,2008). Here we have analyzed ALDH activity in 23 AML cases. In 7 AML cases, a high SSCloALDHbr cell population was identified (median: 10,9%, range 5,24-15,29%). In 16 cases there were rare (<5%) SSCloALDHbr cells. We have analyzed ALDH activity in aberrant marker defined HSCs and LSCs, both present within the same BM samples in 18 AML patients (summarized in Figure 1). In 9 BM AML samples, defined as CD34-, the CD34+ compartment contained only normal CD34+CD38- HSCs. The ALDH activity in the CD34- cells, which includes by definition in this AML subgroup the LSC, is a factor 4,4 (range 1,7-18,9) lower than in the HSC (Figure 1, panel 1). The ALDHbrSSClo cells present in these CD34- AML cases contained both normal CD34+ and CD34- cells. The activity of the normal HSC within this AML BM is similar to that of the normal HSC in NBM of healthy donors (Figure 1, panel 3). In addition, 9 BM AML patients, defined as CD34+ AML and with both marker negative, normal HSCs and marker positive LSCs present, were analyzed for ALDH activity. We show that the marker positive CD34+CD38- LSCs have 7,7 fold (range 1,73-29,2 fold) lower ALDH activity than the marker negative CD34+CD38- HSCs (Figure 1, panel 2). Altogether, we show that, although malignant AML blast cells have varying ALDH activity, a common feature of all AML cases is that the normal HSCs that co-exist with leukemic (stem) cells in the BM of AML patients have a higher ALDH activity as compared to their malignant counterparts (summarized in figure 1). In conclusion, high ALDH activity is an unique marker of normal HSC within the AML BM (irrespective of AML phenotype, CD34+ or CD34-) at diagnosis. Consequently, AML patients with high ALDH activity in the normal HSC might benefit from treatment with alkylating agents such as cyclophosphamide, whereby the difference between the ALDH activity in LSC and HSC defines the therapeutic window. At present, drugs, known to be dependent on low ALDH for proper activity, are tested for their LSC specific killing while sparing the normal HSC. Additionally, transcriptional profiles are obtained from purified ALDH+ HSC and ALDH- LSC. This will enable us to use this general discriminating property to identify molecules that differ between the LSC and HSC and can function as LSC specific therapeutic targets. Disclosures: No relevant conflicts of interest to declare.
Only a minority of cells, the leukemic stem cells (LSCs), within Acute Myeloid Leukemia (AML) are typically responsible for tumor growth and maintenance. Many patients experience a relapse after therapy which originates mainly from the outgrowth of therapy resistant LSC. Therefore, eradication of the LSCs is likely necessary to cure leukemia. Both the normal hematopoietic stem cells (HSCs) and LSCs co-exist in the bone marrow (BM) of leukaemia patients and therefore success of an anti-stem-cell strategy relies on specific induction of LSC death while sparing the normal HSC. In AML, apart from the CD34+CD38- and the side population (SP) compartment, the high aldehyde dehydrogenase (ALDH) activity compartment contains the LSCs. ALDH is a detoxifying enzyme responsible for the oxidation of intracellular aldehydes. Recent data has shown that ALDH is highly expressed in both normal progenitor and stem cells and in AML blast cells. High ALDH activity results in resistance to alkylating agents such as the active derivatives of cyclophosphamide. We have previously shown that CD34+CD38- and SP LSCs can be identified and discriminated from HSCs using stem cell-associated cell surface markers, including C-type lectin-like molecules (CLL-1), lineage markers, such as CD7, CD19, and CD56 and recently cell size characteristics as measured by flow cytometry. Here we have analyzed ALDH activity in normal HSCs and LSCs, both present within the same BM, in 23 AML patient samples. In 7 AML cases, a high SSCloALDHbr cell population was identified (>5%). We show that in 9 BM AML samples, defined as CD34min (ie <1% CD34+ cells, in which the CD34+CD38-cells are all normal HSC), the ALDH activity is lower in the LSC then in the HSC. The activity of the normal HSC within this AML BM is identical as the ALDH activity of normal HSC in NBM of healthy donors. In 9 BM AML patients, defined as CD34+ and with both normal and leukemic CD34+CD38-present, we show that the marker positive CD34+CD38-LSCs have lower ALDH activity then the marker negative CD34+CD38-HSCs. Altogether, we show that, although malignant AML blast cells have varying ALDH activity, a common feature of all AML cases is that the normal HSCs that co-exist with leukemic (stem) cells in the BM of AML patients have a higher ALDH activity as compared to their malignant counterparts. In conclusion, high ALDH activity is an unique marker of normal HSC within the AML BM at diagnosis. Consequently, AML patients with high ALDH activity in the normal HSC might benefit from treatment with alkylating agents such as mafosfamide, whereby the difference between the ALDH activity in LSC and HSC defines the therapeutic window. At present, drugs, known to be dependent on low ALDH for proper activity, are tested for their LSC specific killing while sparing the normal HSC. Citation Information: Clin Cancer Res 2010;16(7 Suppl):A29
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