Rapid decline of chronic myeloid leukemic cells in long-term culture due to a defect at the leukemic stem cell level.

Udomsakdi, C; Eaves, Connie J.; Swolin, Birgitta; Reid, Dianne; Barnett, Michael J.; Eaves, AC

doi:10.1073/pnas.89.13.6192

Cited by 162 publications

(104 citation statements)

References 23 publications

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“…Opinions range from the one extreme, that the great recently been used by Maguer-Satta et al 29 They studied five majority of primitive cells are Ph − , to the other, that many CML patients in whom the primitive cell compartment (LTCIC) are Ph + at least in some patients. 11,[13][14][15][16][17]29,30 However, recent was known to consist predominantly of Ph + cells. By sorting studies demonstrating the existence in CML patients of leuprimitive cells and performing RT-PCR on them individually kemic cells that are capable of reconstituting severe combined they found that BCR/ABL mRNA could be specifically immunodeficient mice, 31 and the well-demonstrated transdetected in about 60-90% of the CML cells in which the actin forming activity of BCR-ABL in experimental systems, [32][33][34] message was present.…”

Section: Resultsmentioning

confidence: 99%

BCR/ABL-negative progenitors are enriched in the adherent fraction of CD34+ cells circulating in the blood of chronic phase chronic myeloid leukemia patients

Grand

Chase

et al. 1997

Leukemia

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Philadelphia chromosome-positive (Ph + ) hemopoietic cells precan be mobilized, presumably from the bone marrow, into the dominate in patients with chronic myeloid leukemia (CML) in blood of CML patients following chemotherapy. 9 The blood of chronic phase, but some Ph − presumably normal stem cells CML patients has also been used for autologous rescue followpersist in most patients. Ph − cells are relatively frequent, coming high-dose therapy and in some cases Ph chromosomepared to mature cell populations, in primitive hemopoietic cell negative recovery has been observed. 10 IntroductionThe results show that primitive BCR/ABL − cells circulate in the blood of chronic phase CML patients. They are enriched Chronic myeloid leukemia (CML) is characterized by a in the fraction of CD34 + cells that adhere to tissue culture reciprocal translocation between chromosomes 9 and 22 plastic and are predominantly CD33, CD38 and HLA-DR anti-(t[9;22][q34;q11]) which results in the formation of the Philagen-negative. These findings support the view that adhesion delphia (Ph) chromosome. 1 At the molecular level, the Ph to plastic is a property of very primitive normal hemopoietic chromosome involves the fusion of the BCR and ABL genes cells, [18][19][20][21][22] and have implications for the use of peripheral and the production of a p210 protein tyrosine kinase. 2,3 It is blood cells for autografting patients with CML. likely that the rearrangement of BCR and ABL is responsible for the expansion of pluripotent leukemic stem cells and the production of large numbers of committed myeloid, erythroid and megakaryocytic progeny in CML. 4 It may also be responMaterials and methods sible for the adhesive defect that characterizes primitive progenitor cells in CML. 5,6 Cells Good evidence for the persistence of normal hemopoietic stem cells in the marrow of patients with CML has been provided by the Ph chromosome-negative recovery of patients Peripheral blood cells were obtained from patients with treated with ␣-interferon 7 and Ph − hemopoiesis seen after chronic phase (CP) CML in the outpatient clinic ( Norway) according to the manufacturer's instructions.

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Section: Resultsmentioning

confidence: 99%

BCR/ABL-negative progenitors are enriched in the adherent fraction of CD34+ cells circulating in the blood of chronic phase chronic myeloid leukemia patients

Grand

Chase

et al. 1997

Leukemia

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“…Nine of these twelve patients were then treated with a-interferon (IFN-a) 1-3 x lo6 units/m2, 3-7 dayslweek; four returned to complete remission, three developed increasing numbers of Ph+ cells, and two are still too early to evaluate. Recently, we have shown that leukemic stem cells, operationally defined as Ph+ LTC initiating cells (LTC-IC), are, on average, present in CML marrow at levels 10-fold lower than their normal counterparts and can be selectively "purged" (by a factor of 30-fold) following incubation for 10 days in LTC [5,6].…”

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confidence: 99%

Allografting in chronic myeloid leukemia with cultured marrow: Update of the vancouver study

et al. 1993

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When chronic myeloid leukemia (CML) marrow is set up in long‐term culture (LTC), Philadelphia chromosome (Ph)‐positive (Ph+) cells typically decline and Ph‐negative (Ph−) hematopoietic cells often become detectable. In 1987, we initiated a study to evaluate the feasibility of using 10‐day cultured marrow autografts to allow intensive treatment of CML. Patients were selected on the basis of a previous assessment of the frequencies of normal and leukemic LTC‐initiating cells (LTC‐IC) remaining in their marrow after 10 days of LTC. Of the 87 patients evaluated, 36 (41%) were considered eligible, and 22 (15 in first chronic phase [CP], Group 1; and 7 with more advanced disease, Group 2) were autografted with 10‐day cultured marrow after intensive therapy. Satisfactory hematological recovery occurred in 16 patients, and of these, only Ph− cells were detected in 13 (nine in Group 1), with 76–94% Ph− cells in the other three (two in Group 1). Ph+ cells reappeared between 4 and 36 months post‐autograft in all but one of the 13 patients in whom complete (morphological and cytogenetic) remission had been achieved; the remaining patient died in remission. Nine of these twelve patients were then treated with α‐interferon (IFN‐α) 1–3 × 106 units/m2, 3–7 days/week; four returned to complete remission, three developed increasing numbers of Ph+ cells, and two are still too early to evaluate. Fifteen patients (12 in Group 1) remain alive and well, nine in hematological remission (eight in Group 1), 9 to 64 months (median 28) post‐autograft. Another patient (Group 1) remains alive 30 months post‐autograft but has developed blast phase disease. Four patients (all in Group 1) continue in complete remission after treatment with IFN‐α. These results establish the feasibility of using cultured marrow autografts for the treatment of CML.

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“…Initially, the finding that such cells were present in markedly elevated numbers in the peripheral blood, as anticipated from previous studies of clonogenic cells, led to the expectation that their numbers might be similarly elevated in the marrow. In fact, the opposite appears to be the case [19] (see also Fig. IB).…”

Section: Quantitation Of Normal and CML Stem Cellsmentioning

confidence: 85%

“…The most dramatic differential effect of any treatment thus far examined appears to be that afforded by simply placing a CML marrow autograft in culture for a period of 7 to 10 days [19]. Under these conditions, normal LTC-IC numbers remain at, or may even increase to slightly above, input numbers whereas the Ph-positive LTC-IC decline precipitously, on average by a factor of -30 (Fig.…”

mentioning

confidence: 99%

Biological strategies for the selective manipulation of normal and leukemic stem cells

Eaves¹,

Cashman²,

Zoumbos³

et al. 1993

Stem Cells

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Abstract. Recent developments have occurred in the identification and quantitation of a very primitive type of hematopoietic cell (referred to as a long-term culture initiating cell or LTC-IC) using defined long-term culture conditions. These have facilitated investigations of the numbers and prop erties of both normal and leukemic LTC-IC in patients with chronic myeloid leukemia (CML). Such studies have revealed that the marrow of many chronic phase patients contains a substantlsl population of normal LTC-IC that are lunctionally intact albeit suppressed in vivo. Leukemic LTC-IC are typically less numerous in the marrow of these patients but are found in elevated numbers in the peripheral blood which, on average, in total contains more leukemic LTC-IC than the marrow when the WBC count rises above 10" per liter. However, a very marked heterogeneity in all of these parameters exists among individual patients. Some of the properties of leukemic LTC-IC are indistinguishable from those of their normal counterparts. Others, particularly those typically assodated with an activated state, are altered, although frequently in only 90% (or less) of the leukemic LTC-IC. A more marked disparity between primitive normal and leukemic LTC-IC is seen in terms of their relative abilities to maintain their numbers in vitro. At the level of primitive donogenic cells, the leukemic population has heen shown to exhibit an increased rate of turnover. This appears to be due to an inability of these cells to respond to the cytostatic effects of macrophage inflammatory protein-la --la).Tbese findingy provide new insights into the biology of CML and highlight the power of quantitative assays to guide the development of more generally applicable curative therapies.

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Rapid decline of chronic myeloid leukemic cells in long-term culture due to a defect at the leukemic stem cell level.

Cited by 162 publications

References 23 publications

BCR/ABL-negative progenitors are enriched in the adherent fraction of CD34+ cells circulating in the blood of chronic phase chronic myeloid leukemia patients

BCR/ABL-negative progenitors are enriched in the adherent fraction of CD34+ cells circulating in the blood of chronic phase chronic myeloid leukemia patients

Allografting in chronic myeloid leukemia with cultured marrow: Update of the vancouver study

Biological strategies for the selective manipulation of normal and leukemic stem cells

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