SP/drug efflux functionality of hematopoietic progenitors is controlled by mesenchymal niche through VLA-4/CD44 axis.

Hematopoiesis is orchestrated by interactions between hematopoietic stem/progenitor cells (HSPCs) and stromal cells within bone marrow (BM) niches. Side population (SP) functionality is a major characteristic of HSPCs related to quiescence and resistance to drugs and environmental stresses. At steady state, SP cells are mainly present in the BM and are mostly absent from the circulation except in stress conditions, raising the hypothesis of the versatility of the SP functionality. However, the mechanism of SP phenotype regulation is unclear. Here we show for the first time that the SP functionality can be induced in lin(-) cells from unmobilized peripheral blood after nesting on mesenchymal stromal cells (MSCs). This MSC-induced SP fraction contains HSPCs as demonstrated by their (i) CD34(+) cell percentage, (ii) quiescent status, (iii) in vitro proliferative and clonogenic potential, (iv) engraftment in NSG (NOD SCID gamma chain) mice and (v) stemness gene expression profile. We demonstrate that SP phenotype acquisition/reactivation by circulating lin(-) cells is dependent on interactions with MSCs through VLA-4/α4ß1-integrin and CD44. A similar integrin-dependent mechanism of SP phenotype acquisition in acute myeloid leukemia circulating blasts suggests an extrinsic regulation of ATP-binding cassette-transporter activity that could be of importance for a better understanding of adhesion-mediated chemoresistance mechanisms.

New mutations of MPL in primitive myelofibrosis: only the MPL W515 mutations promote a G1/S-phase transition.

MPL (or thrombopoietin receptor, TPO-R) 515 mutations have recently been described in 5-10% of primitive myelofibrosis (PMF) cases as decisive oncogenic events capable of triggering the disease. Here we report additional mutations located in exon 10 of MPL in PMF patients. We investigated whether these new mutations also lead to cell transformation. MPL exon 10 was systematically sequenced in 100 PMF patients. Seven different mutations were found in eight patients. We introduced each MPL mutant in Ba/F3 cells to determine whether they correspond to gain-of-function mutations. Only MPL W515 mutations induced (1) Ba/F3 proliferation independently of growth factors, (2) tumorigenesis in nude mice, (3) spontaneous activation of JAK/STAT, RAS/MAPK and PI3K transduction pathways and (4) increased S phase of cell cycle. Similar to all other myeloproliferative disorder oncogenic events identified to date, these results demonstrate that only the detected MPL W515 mutations trigger spontaneous MPL activation leading to a G(1)/S transition activation. The other mutations are devoid of significant transforming activity but may synergize with JAK2 V617F or other not yet characterized molecular events.

Altered transcription of the stem cell leukemia gene in myelofibrosis with myeloid metaplasia.

An increased number of circulating CD34+ hematopoietic progenitors with a prominent proliferation of the megakaryocytic (MK) population are the hallmarks of the myeloproliferation in myelofibrosis with myeloid metaplasia (MMM). Analyzing the potential contribution of the stem cell leukemia (SCL) gene in MMM myeloproliferation was doubly interesting for SCL is expressed both in primitive-uncommitted progenitor cells and erythroid/MK cells, its transcription differentially initiating from promoter 1b and 1a, respectively. Our results show that: (i) the expression of SCL transcript is increased in peripheral blood mononuclear cells (PBMCs) from patients; (ii) SCL gene transcription is altered in MMM CD34+ progenitor cells sorted into CD34+CD41+ and CD34+CD41- subpopulations. Actually, in patients, SCL transcription initiated at promoter 1b is restricted to primitive CD34+CD41- progenitor cells, while it is detectable in both cell subsets from healthy subjects; (iii) the full-length isoform of SCL protein is present in patients' CD34+ cells and in PBMC; in the latter the SCL-expressing cells mainly belong to the MK lineage in which its sublocalization is both nuclear and cytoplasmic, which contrasts with the sole nuclear staining observed in normal MK cells. Our demonstration of altered expression and transcription of SCL in patients' hematopoietic cells emphasizes the possible contribution of this regulatory nuclear factor to the hematopoietic dysregulation, which is a feature of myelofibrosis with myeloid metaplasia.

Detection of a functional hybrid receptor gammac/GM-CSFRbeta in human hematopoietic CD34+ cells.

A functional hybrid receptor associating the common gamma chain (gammac) with the granulocyte/macrophage colony-stimulating factor receptor beta (GM-CSFRbeta) chain is found in mobilized human peripheral blood (MPB) CD34+ hematopoietic progenitors, SCF/Flt3-L primed cord blood (CB) precursors (CBPr CD34+/CD56-), and CD34+ myeloid cell lines, but not in normal natural killer (NK) cells, the cytolytic NK-L cell line or nonhematopoietic cells. We demonstrated, using CD34+ TF1beta cells, which express an interleukin (IL)-15Ralpha/beta/gammac receptor, that within the hybrid receptor, the GM-CSFRbeta chain inhibits the IL-15-triggered gammac/JAK3-specific signaling controlling TF1beta cell proliferation. However, the gammac chain is part of a functional GM-CSFR, activating GM-CSF-dependent STAT5 nuclear translocation and the proliferation of TF1beta cells. The hybrid receptor is functional in normal hematopoietic progenitors in which both subunits control STAT5 activation. Finally, the parental TF1 cell line, which lacks the IL-15Rbeta chain, nevertheless expresses both a functional hybrid receptor that controls JAK3 phosphorylation and a novel IL-15alpha/gammac/TRAF2 complex that triggers nuclear factor kappaB activation. The lineage-dependent distribution and function of these receptors suggest that they are involved in hematopoiesis because they modify transduction pathways that play a major role in the differentiation of hematopoietic progenitors.

Effects of human fibroblasts from myelometaplasic and non-myelometaplasic hematopoietic tissues on CD34+ stem cells.

Fibroblasts demonstrate different phenotypes and functions according to the tissue of origin and its physiopathologic state. We previously showed that fibroblasts isolated in culture from myelometaplasic (MM) spleen differed phenotypically from fibroblasts from normal bone marrow (BM). We compared the influence of each type of fibroblasts on the behavior of CD34+ stem cells. Expansion of nucleated cells was observed when blood CD34+ cells were co-cultured for 3 weeks with MM spleen-derived fibroblasts in monolayers. Myeloid cell differentiation was also observed as indicated by a decline in CD34+ cells and increases in CD14+, CD15+ and CD41+ cells. This myeloid differentiation was enhanced in the presence of MM spleen compared with normal BM-derived fibroblasts. Similarly, proliferation and differentiation of BM CD34+ cells was better in the presence of BM rather than MM spleen-derived fibroblasts. In addition, fibroblasts from MM spleen also induced a differentiation of CD56+ natural killer (NK) cells whereas BM-derived fibroblasts did not. Overall, the data indicate that cultured fibroblasts from diseased tissue have distinct growth and differentiation regulatory characteristics. They also suggest a role for these cells in hematopoietic disorders.

Involvement of the fibrogenic cytokines, TGF-beta and bFGF, in the pathogenesis of idiopathic myelofibrosis.

Idiopathic Myelofibrosis (IMF), is a chronic myeloproliferative disorder characterized by the association of myeloproliferation and myelofibrosis. The pathophysiological mechanisms resulting in this disease remain still unclear. The myeloproliferation appeared to result from the clonal amplification of hematopoietic progenitors. In contrast, fibroblasts participating in myelofibrosis were shown to be polyclonal, thus suggesting that myelofibrosis was a reactive process. We studied the role of two growth factors TGF-beta and bFGF, which display potent fibrogenic properties and are major regulators of primitive hematopoiesis, in IMF pathogenesis. We demonstrated an increase of TGF-beta and bFGF expression in circulating megakaryocytic cells and platelets, together with alterations of the expression of these cytokines and their receptors in hematopoietic CD34+ progenitor cells from IMF patients. Our results suggested that TGF-beta and bFGF are involved both in myelofibrosis and myeloproliferation which characterize IMF.

CD9 and megakaryocyte differentiation.

It is shown that the tetraspanin CD9 has a complex pattern of distribution in hematopoietic cells and is heterogeneously expressed on human bone marrow CD34(+) cells. CD34(high)CD38(low)Thy1(+) primitive progenitors are contained in the population with intermediate CD9 expression, thus suggesting that CD9 expression may precede CD38 appearance. Cell sorting shows that colony-forming unit (CFU)-GEMM and CFU-GM are present in high proportions in this fraction and in the fraction with the lowest CD9 expression. Cells with the highest level of CD9 are committed to the B-lymphoid or megakaryocytic (MK) lineages, as shown by the co-expression of either CD19 or CD41/GPIIb and by their strong potential to give rise to CFU-MK. In liquid cultures, CD9(high)CD41(neg) cells give rise to cells with high CD41 expression as early as 2 days, and this was delayed by at least 3 to 4 days for the CD9(mid) cells; few CD41(high) cells could be detected in the CD9(low) cell culture, even after 6 days. Antibody ligation of cell surface CD9 increased the number of human CFU-MK progenitors and reduced the production of CD41(+) megakaryocytic cells in liquid culture. This was associated with a decreased expression of MK differentiation antigens and with an alteration of the membrane structure of MK cells. Altogether these data show a precise regulation of CD9 during hematopoiesis and suggest a role for this molecule in megakaryocytic differentiation, possibly by participation in membrane remodeling. (Blood. 2001;97:1982-1989)

Chemokine SDF-1 enhances circulating CD34(+) cell proliferation in synergy with cytokines: possible role in progenitor survival.

The chemokine stromal cell-derived factor-1 (SDF-1), and its receptor, CXCR-4, have been implicated in the homing and mobilization of human CD34(+) cells. We show here that SDF-1 may also be involved in hematopoiesis, promoting the proliferation of human CD34(+) cells purified from normal adult peripheral blood (PB). CXCR-4 was expressed on PB CD34(+) cells. The amount of CXCR-4 on PB CD34(+) cells was 10 times higher when CD34(+) cells were purified following overnight incubation. CXCR-4 overexpression was correlated with a primitive PB CD34(+) cell subset defined by a CD34(high) CD38(low)CD71(low)c-Kit(low)Thy-1(+) antigenic profile. The functional significance of CXCR-4 expression was ascertained by assessing the promoting effect of SDF-1alpha on cell cycle, proliferation, and colony formation. SDF-1 alone increased the percentage of CD34(+) cells in the S+G(2)/M phases and sustained their survival. In synergy with cytokines, SDF-1 increased PB CD34(+) and CD34(high)CD38(low) cell expansion and colony formation. SDF-1 also stimulated the growth of colonies derived from primitive progenitors released from quiescence by anti-TGF-beta treatment. Thus, our results shed new light on the potential role of this chemokine in the stem cell engraftment process, which involves migration, adhesion, and proliferation. Furthermore, both adhesion-induced CXCR-4 overexpression and SDF-1 stimulating activity may be of clinical relevance for improving cell therapy settings in stem cell transplantation.

Dual implication of fibrogenic cytokines in the pathogenesis of fibrosis and myeloproliferation in myeloid metaplasia with myelofibrosis.

Though the diagnostic criteria of myeloid metaplasia with myelofibrosis (MMM) are now well established, the origin and pathophysiological mechanisms of this myeloproliferative disorder remain unclear. Concerning its pathophysiology, myeloproliferation and myelofibrosis are the intrinsic characteristics of the disease. Whereas the myeloproliferation was shown to result from a clonal amplification of primitive progenitor cells, fibroblast proliferation appeared to be polyclonal, thus suggesting that myelofibrosis was a reactive process. The myeloproliferation observed in MMM patients is characterized by an increased number of circulating CD34(+) hematopoietic progenitors. When cultured at high concentration without added exogenous growth factors, unpurified progenitors from MMM patients gave rise to spontaneous colonies of all myeloid lineages. Such an autonomous growth disappeared when purified CD34(+) progenitors were plated. These results suggested that growth factors are involved in the dysregulation of proliferation and/or differentiation of MMM hematopoietic progenitors. Cytokines such as PDGF, TGF-beta, and bFGF, produced mainly by megakaryocytes, have been proposed to be involved in the abnormal activation of fibroblasts, resulting in fibrosis. Recently the role of the fibrogenic cytokines, TGF-beta and bFGF, in the regulation of primitive hematopoiesis has been reported. The aim of this review is to address the question of the potential dual implication of TGF-beta and bFGF in the pathogenesis of both myelofibrosis and myeloproliferation in MMM patients.

Differential expression of protein kinase C isoform transcripts in human hematopoietic progenitors undergoing differentiation.

Protein kinase C (PKC), a key component of the signaling pathways leading to proliferation and differentiation, consists of a family closely related serine/threonine protein kinases. The mRNA expression of these PKC isoforms has been characterized during hematopoietic differentiation. Using the reverse-transcriptase polymerase chain reaction technique, we have analyzed the levels of isoform transcripts in bone marrow CD34(+) hematopoietic progenitors and their progeny differentiated along erythroid, megakaryocyte, or granulocyte/monocyte lineages, upon exposure to growth factors. In contrast with isoforms alpha, beta(I), beta(II), delta, and epsilon, ubiquitously expressed, isoforms theta, eta/L, zeta, and iota/lambda exhibited a lineage-restricted expression. These qualitative changes, which allow to distinguish the erythroid and megakaryocyte phenotypes from the granulocyte/monocyte phenotype, include zeta exclusively upregulated in granulocytes/monocytes and theta, eta/L, and iota/lambda exclusively expressed in megakaryocytes and erythroblasts. In contrast, erythroblasts and megakaryocytes, which supposedly share a common bipotential progenitor, displayed only quantitative changes. These results evidence the selective expression of PKC isoforms at transcriptional and/or posttranscriptional levels in hematopoietic progenitors induced to differentiate, which may suggest a differential contribution of individual isoforms to cellular signaling.