Interferon-alpha overrides the deficient adhesion of chronic myeloid leukemia primitive progenitor cells to bone marrow stromal cells

Primitive blast colony-forming cells (BI-CFC) from chronic myeloid leukemia (CML) patients are defective in their attachment to bone marrow-derived stromal cells compared with normal BI-CFC. We investigated the effect of recombinant interferon-alpha 2a (IFN-alpha) on this interaction between hematopoietic progenitor cells and bone marrow-derived stromal cells by culturing normal stromal cells with IFN-alpha (50 to 5,000 U/mL). At 50 U/mL we found that: (1) the capacity of stromal cells to bind two types of CML primitive progenitor cells (BI-CFC and long-term culture-initiating cells) was increased; and (2) the amount of sulfated glycosaminoglycans (GAGs) in the stromal layer was increased. However, sulfated GAGs were not directly involved in binding CML BI-CFC, unlike binding by normal BI-CFC, which is sulfated GAG-dependent. Neuraminidase-treated control stromal cells bound an increased number of CML BI-CFC, reproducing the effect of IFN-alpha, whereas the binding to IFN-alpha-treated stromal cells was unaffected by neuraminidase treatment. Thus, the enhanced attachment by primitive CML progenitor cells to INF-alpha-treated stromal cells might be due to changes in the neuraminic acid composition in the stromal cell layer. Our in vitro evidence may provide insights into the mechanism of action of IFN-alpha in vivo. Prolonged administration may alter the marrow microenvironment in some patients such that it can restrain the aberrant proliferation of Philadelphia chromosome (Ph)-positive stem cells while permitting Ph-negative stem cells to function normally.     

Increased DR antigen expression by committed hemopoietic progenitor cells but not primitive progenitor cells in chronic myeloid leukemia

We used a complement-dependent cytotoxic assay to study the expression of DR antigens by hemopoietic progenitor cells derived from normal marrow and from the blood of patients with chronic phase chronic myeloid leukemia (CML). Almost all normal and CML day-12 granulocyte-macrophage colony-forming cells (d12 GM-CFC) and erythroid burst-forming units (BFU-E) expressed DR antigens. A primitive progenitor cell, the "blast colony-forming cell" (Bl-CFC), also expressed DR antigens whether derived from normal marrow or CML blood. The expression of DR antigen by normal and CML Bl-CFC was similar but the density of DR antigens on CML d12 GM-CFC and BFU-E was much greater than that of their counterparts from normal marrow. The similarity in DR antigen density on normal and CML Bl-CFC means that purging of CML marrow using a DR-specific antibody would not select in favor of normal cells and thus would not be useful in an autograft setting.     

Phenotypic heterogeneity of primitive leukemic hematopoietic cells in patients with chronic myeloid leukemia.

The peripheral blood of chronic myeloid leukemia (CML) patients with chronic-phase disease and elevated white blood cell (WBC) counts typically contains markedly increased numbers of a variety of neoplastic pluripotent and lineage-restricted hematopoietic progenitors. These include cells detected in standard colony assays as well as their more primitive precursors. The latter are referred to as long-term culture-initiating cells (LTC-IC) because of their ability to generate clonogenic cell progeny detectable after a minimum of 5 weeks incubation on competent fibroblast feeder layers. In this study, we have investigated a number of the properties of the LTC-IC and clonogenic cells present in the blood of such CML patients with high WBC counts. This included an analysis of the light scattering properties of these progenitors, as well as their expression of CD34 and HLA-DR, Rhodamine-123 staining, and in vitro sensitivity to 4-hydroperoxycyclophosphamide. In the case of LTC-IC, the production of different types of lineage-restricted and multipotent progeny was also analyzed. Most of the circulating LTC-IC and clonogenic cells in the CML patients studied (on average approximately 70% and approximately 90%, respectively) showed features of proliferating or activated cells. This is in marked contrast to the majority of progenitors in the blood of normal individuals and most of the LTC-IC in normal marrow, all of which exhibit a phenotype expected of quiescent cells. Interestingly, a significant proportion of the circulating clonogenic cells and LTC-IC in the CML samples studied (on average approximately 10% and approximately 30%, respectively) appeared to be phenotypically similar to normal circulating progenitors, although their absolute numbers were indicative of a neoplastic origin. Both phenotypes of circulating CML clonogenic cells and LTC-IC could be obtained at approximately 10% to 20% purity by differential multiparameter sorting. These findings suggest that expansion of the Philadelphia chromosome-positive clone at the level of the earliest types of hematopoietic cells results from the activation of mechanisms that enable some, but not all, signals that block the cycling of normal stem cells to be bypassed or overcome. In addition, they provide strategies for purifying these primitive leukemic cells that should facilitate further analysis of the mechanisms underlying their abnormal proliferative behavior.     

Regulated proliferation of primitive hematopoietic progenitor cells in long-term human marrow cultures

We have examined the cycling status of various classes of erythroid and granulopoietic progenitor populations maintained for many weeks in standard normal long-term human marrow cultures. These were initiated with a single inoculum of marrow aspirate and were routinely fed by weekly removal of half of the nonadherent cells and replacement of half of the growth medium. Progenitors of large erythroid colonies (more than eight erythroblast clusters) present in the nonadherent fraction and progenitors of small granulocyte/macrophage colonies (fewer than 500 cells) present in both the nonadherent and adherent fractions were found to be actively cycling at all times examined (28% to 63% kill following a 20-minute exposure to 20 microCi/mL of high specific activity 3H-thymidine). In contrast, progenitors of large granulocyte/macrophage colonies (more than 500 cells) and progenitors of large erythroid colonies (more than eight erythroblast clusters), present in the adherent layer, consistently alternated between a quiescent state at the time of each weekly medium change and a proliferating state two to three days later (0% to 13% kill and 21% to 49% kill, respectively). Additional experiments revealed that the activation of primitive progenitors in the adherent layer was not dependent on the addition of fresh glutamine or hydrocortisone, nor on the physical manipulations involved in changing the growth medium. These studies provide the first direct evidence that normal long-term human marrow cultures support the continued turnover of a variety of early hematopoietic progenitor cell types. Further, they indicate that the proliferative activity of the most primitive of these progenitors is regulated by stage-specific cell-cell interactions that are subject to manipulation.     

Unresponsiveness of primitive chronic myeloid leukemia cells to macrophage inflammatory protein 1 alpha, an inhibitor of primitive normal hematopoietic cells.

Most primitive hematopoietic cells appear to be normally quiescent in vivo, whereas their leukemic counterparts in patients with chronic myeloid leukemia (CML) are maintained in a state of rapid turnover. This difference is also seen in the long-term culture system, where control of primitive hematopoietic progenitor proliferation is mediated by interactions of these cells with marrow-derived mesenchymal cells of the fibroblast lineage. We now show that exogenous addition of macrophage inflammatory protein 1 alpha (MIP-1 alpha) to normal long-term cultures can reversibly and specifically block the activation of "primitive" (high proliferative potential), but not "mature" (lower proliferative potential), progenitors in the adherent layer of these cultures. Moreover, addition of MIP-1 beta after primitive-progenitor activation can prevent the subsequent return of these cells to a quiescent state a few days later as shown previously in similar experiments using antibodies to transforming growth factor beta. This suggests that the level of MIP-1 alpha (or a related MIP-1 alpha agonist) produced in LTCs, like the level of transforming growth factor beta, may be necessary, but is not on its own sufficient, to mediate the inhibitory activity of the regulatory cells in the adherent layer. Addition of MIP-1 alpha to similar long-term cultures containing normal marrow adherent layers but supporting exclusively neoplastic (CML) hematopoiesis did not block the cycling of primitive neoplastic progenitors. A defect in the responsiveness of CML cells to MIP-1 alpha (or a similarly acting chemokine) would explain their deregulated proliferative behavior in this model and, by extrapolation to the in vivo setting, suggests a molecular mechanism whereby the leukemic clone may become amplified at the stem-cell level. In addition, these findings suggest approaches to the therapy of CML, using inhibitors such as MIP-1 alpha for the protection of primitive normal cells.     

Binding of primitive hematopoietic progenitor cells to marrow stromal cells involves heparan sulfate.

Blast colony-forming cells (BI-CFC) and pre-colony-forming unit-granulocyte, monocyte (CFU-GM) in human bone marrow bind to marrow-derived stromal layers grown in the presence of methylprednisolone (MP+), but do not bind to stroma grown without MP (MP-). The BI-CFC bind to stroma and form colonies when overlaid with agar; the pre-CFU-GM bind to stroma and release CFU-GM into the supernatant culture medium (delta assay). These two classes of progenitor may represent similar stages of hematopoietic cell development. Their binding to stroma depends on the presence of heparan sulfate proteoglycan (HS-PG) in the extracellular matrix secreted by the stromal cells. Here, we have analyzed the functional and biochemical properties of HS-PG isolated from MP+ and MP- stromal cultures. HS-PG or isolated HS glycosaminoglycan (GAG) side chains partially blocked progenitor cell binding when they were added to the 2-hour binding phase of the BI-CFC or delta assays. Gel electrophoresis of HS-PG resolved more bands in matrix preparations from MP+ cultures than in preparations from MP- cultures. The blocking activity of the eluted MP+ HS-PG bands depended partly on the amount of GAG attached to the protein core and presumably partly on the structure of the core itself. Time course studies demonstrated that the HS-dependent phase of the binding interaction was limited to the first 30 to 60 minutes of the 2-hour binding phase. The different blocking effects of MP+ and MP- HS indicate that they have different biochemical properties. The HS-GAG in MP+ stroma has a higher degree of sulfation and a greater negative charge to mass ratio compared with MP- HS-GAG. Variations in HS may determine specific binding by hematopoietic progenitor cells and a heparan sulfate receptor is envisaged as acting in concert with further cell adhesion molecules (CAMs) on the progenitor cell surface.     

Unregulated proliferation of primitive chronic myeloid leukemia progenitors in the presence of normal marrow adherent cells.

Previous studies have shown that Philadelphia (Ph1) chromosome-positive chronic myeloid leukemia (CML) results from the abnormal expansion at the pluripotent stem cell level of a single clone of hemopoietic cells. Although it seems likely that this is related to the heightened proliferative activity characteristic of primitive CML progenitor cell types, the underlying mechanism is unknown. In this report we show that either normal or CML peripheral blood progenitors can be maintained on preestablished normal marrow adherent layers for periods of 1-2 months. Under these conditions numbers of both normal and neoplastic progenitors are usually higher in the adherent layer than in the nonadherent fraction. Moreover, the number of primitive progenitors of high proliferative potential present in the adherent layer is sufficient to allow their cycling status to be determined. Such measurements demonstrate that primitive normal progenitors of blood origin, when cultured in the presence of a preestablished adherent marrow feeder layer, go in and out of cycle after each medium change but in the absence of a feeder layer remain continuously in cycle. In contrast, primitive CML progenitors of either blood or marrow origin cycle continuously regardless of the presence or absence of an adherent feeder layer. We suggest that early expansion of the CML clone is related to an ability of the neoplastic stem cells to ignore or overcome a negative regulatory signal produced by nonneoplastic adherent marrow cells whose normal function is to maintain the stem cell reserve in a quiescent state.     

Persistence of myeloid progenitor cells expressing BCR-ABL mRNA after allogeneic bone marrow transplantation for chronic myelogenous leukemia

Previous studies have shown that tumor-specific bcr-abl mRNA can often be detected by polymerase chain reaction. (PCR) for months to years after allogeneic bone marrow transplantation (BMT) for chronic myelocytic leukemia (CML). Nevertheless, the presence of bcr-abl mRNA by itself does not invariably predict for clinical relapse post-BMT. This has led to the hypothesis that bcr-abl mRNA might be expressed in cells that have lost either proliferative or myeloid differentiation potential. To directly characterize the cells detected by PCR in patients with CML after allogeneic BMT, we first identified five individuals in whom PCR-positive cells could be detected at multiple times post-BMT. Bone marrow samples from these individuals were cultured in vitro and single erythroid, granulocytic, and macrophage colonies, each containing 50 to 100 cells, were examined for the presence of bcr-abl mRNA by PCR. PCR-positive myeloid colonies could be detected in four of five individuals in marrow samples obtained 5 to 56 months post-BMT. Overall, 7 of 135 progenitor cell colonies (5.2%) were found to be PCR-positive. The expression of bcr-abl mRNA appeared to be equally distributed among committed erythroid, macrophage, and granulocyte progenitors. These patients have now been followed-up for an additional 20 to 33 months from the time of progenitor cell PCR analysis but only one of these individuals has been found to have cytogenetic evidence of recurrent Ph+ cells. These results show that long-term persistence of PCR-detectable bcr-abl mRNA after allogeneic BMT can be caused by the persistence of CML-derived clonogenic myeloid precursors that have survived the BMT preparative regimen. These cells continue to have both proliferative and myeloid differentiation capacity in vitro. Nevertheless, these PCR-positive cells do not appear to either expand or differentiate in vivo for prolonged periods, suggesting the presence of mechanisms for suppression of residual clonogenic leukemia cells in vivo.     

实时定量PCR监测造血干细胞移植后BCR/ABL融合基因的表达

目的监测慢性粒细胞白血病（CML）患者异基因造血干细胞移植（allo-HSCT）后BCR／ABL融合基因表达水平的动态变化,从而判断移植效果,指导临床治疗。方法应用Taqman实时定量RT-PCR方法,以B-actin作为内参照,检测10例初发CML患者及25例接受allo-HSCT治疗的CML患者在移植前、后不同时段外周血中BCR／ABL mRNA表达水平。结果15例接受移植的患者移植前、移植后1、2个月的NBCR／ABL（％）中位数分别为：6．57（0．14～38．83）、0．10（0～1．71）、0（0～0．52）,3个月后全部为0。移植后早期检测BCR／ABL转录本较移植前逐渐下降,移植后1、2个月NBCR／ABL（％）均较移植前下降（x^2均为13．07,P〈O．01）;移植后2个月较1个月下降（x^2=8．10,P〈0．01）。其余10例患者从移植后3～43个月不同时段起连续检测NBCR/ABL（％）也全部为0。结论实时定量RT-PCR方法检测CML患者的BCR／ABL融合基因的表达,操作迅速,灵敏度、特异性好,用于移植后微小残留病的检测对评估预后并指导临床治疗具有重要意义。     

Nonclonal hemopoietic progenitor cells detected in long-term marrow cultures from a Turner syndrome mosaic with chronic myeloid leukemia

We have investigated the clonality of Ph1-negative hemopoietic progenitor cells appearing in long-term marrow cultures established with cells from a mosaic Turner syndrome patient (46,XX/45,X) with Ph1- positive chronic myeloid leukemia (CML). The Ph1-positive clone had been shown previously to have arisen from a cell of the 45,X lineage. At the time of the present study, the patient was five years post- diagnosis and had been off chemotherapy for two months following a year of treatment for lymphoid blast crisis. All analyzed unstimulated marrow metaphases and each of 23 individually analyzed erythroid and granulocyte colonies produced in assays of the starting marrow were 45,X,Ph1. Pooled granulocyte colonies from the same assays yielded four metaphases that were 45,X,Ph1 and one that was 46,XX. Very few hemopoietic progenitors were detected in long-term cultures at any time; however, all of four individually analyzed large granulocyte colonies and a pooled granulocyte colony preparation obtained from assays of 4- to 6-week-old adherent layers yielded exclusively 46,XX metaphases. These results provide evidence that non-clonal progenitors can persist in patients with CML, even after the onset and treatment of blast crisis, and that the long-term marrow culture system provides a sensitive method for detecting such cells.     

Autografting with philadelphia chromosome-negative mobilized hematopoietic progenitor cells in chronic myelogenous leukemia

Intensive chemotherapy given in early chronic phase of chronic myelogenous leukemia (CML) has resulted in high numbers of circulating Philadelphia (Ph) chromosome-negative hematopoietic progenitor cells (HPC). We have autografted 30 consecutive patients with CML in chronic phase with HPC collected in this way to facilitate restoration of Ph-negative hematopoiesis in bone marrow after high-dose therapy. Hematopoietic recovery to greater than 0.5 x10(9)/L neutrophils and to greater than 25 x 10(9)/L platelets occurred in all patients, a median of 13 (range, 9 to 32) days and 16 (range, 6 to 106) days postautograft, respectively. Regenerating marrow cells were Ph-negative in 16 (53%) patients and greater than 66% Ph-negative in 10 (33%) patients. Twenty-eight patients are alive 6 to 76 months (median, 24 months) after autografting. Three patients have developed blast crisis from which 2 have died. Eight patients are in complete cytogenetic remission at a median of 20 (range, 6 to 44) months with a median ratio BCR-ABL/ABL of 0.002 (range, <0.001 to 0.01). Eight patients are in major cytogenetic remission at a median of 22 (range, 6 to 48) months. No patient died as a consequence of the treatment. All patients had some degree of stomatitis that was severe in 15 (50%) patients. Gastrointestinal and hepatic toxicities were observed in about one fourth of patients. Thus, autografting with Ph-negative mobilized HPC can result in prolonged restoration of Ph-negative hematopoiesis for some patients with CML; moreover, most autograft recipients report normal or near normal activity levels, suggesting that this procedure need not to be associated either with prolonged convalescence or with chronic debility.     

Acute lymphoblastic leukemia blast cells do not inhibit bone marrow hematopoietic progenitor colony formation

In newly diagnosed patients with acute lymphoblastic leukemia (ALL), bone marrow (BM) morphology always shows "replacement" by blasts with decreased or absent normal hematopoietic elements. To answer the question of whether ALL blasts inhibit replication and maturation of normal marrow progenitors, we studied the interaction of normal marrow with BM specimens from 16 new cases of ALL. Irradiated ALL blasts, supernatant derived from ALL blasts in suspension cultures, and conditioned medium prepared from ALL blasts augmented the colony-forming ability of normal marrow erythroid burst-forming unit (BFU-E), granulocyte-macrophage colony-forming unit (CFU-GM), megakaryocyte colony-forming unit (CFU-MK), and multilineage colony-forming unit (CFU-GEMM) progenitors. In sharp contrast to published data on the suppressive effects of acute myeloblastic leukemia cells on normal hematopoiesis in vitro, our results indicate that the growth advantage of ALL cells over normal marrow elements is not mediated through an inhibitory mechanism derived from leukemia cells.     

Chronic myeloid leukemia presenting ALL-type BCR/ABL transcript

Summary We assessed the origin of peripheral blood cells and bone marrow cells of 92 samples obtained from 19 patients after allo BMT by two-step polymerase chain reaction (PCR) amplification of MCT118, one of the variable number of tandem repeat regions (VNTR) which has a different length in 19 of 32 sibling pairs examined, that can detect the DNA pattern of a minor cell population of only 1% without using radioisotopes. Mixed chimerism (MC) was detected in the hematopoietic cells of four patients. Two patients who showed progressive MC developed relapse of leukemia 3 months and 4 months after the detection of MC, and two patients died with bone marrow hypoplasia 61 days and 7 months after BMT. These data suggest the clinical importance of analyzing the correlation of MC and clinical complications after BMT by this method, which can be used to monitor MC in about two thirds of allo BMT patients with an adequate sensitivity.     

Isolation of myeloid progenitor cells from peripheral blood of chronic myelogenous leukemia patients

Myeloid progenitor cells (colony- and cluster-forming cells in semisolid medium, CFU-GM) were purified from the peripheral blood of chronic myelogenous leukemia (CML) patients. Lymphocytes, monocytes, and most immature myeloid cells were simultaneously depleted with specific monoclonal antibodies using an erythrocyte rosette technique for cell separation. Cells expressing Ia-like antigen were then selected from the residual cell population. Day 7 CFU-GM were enriched 44--116-fold in the IA+ cell fraction, when compared to the unseparated cells, and up to 47% of the cells could form a myeloid colony or cluster in culture. This cell fraction contained up to 92% undifferentiated blasts, with the remainder mostly promyelocytes. The enriched CFU-GM cells were dependent on an exogenous supply of colony- stimulating factor for growth, and colony formation was linear with cell concentration over a large range (10(4)-10(1) cells/ml). This technique of rosette depletion and enrichment with specific monoclonal antibodies provides a unique method for purifying a homogenous population of myeloid precursor cells with defined surface antigen characteristics.