Christie M. Traycoff

Efficient retrovirus-mediated transfer of the multidrug resistance 1 gene into autologous human long-term repopulating hematopoietic stem cells

Pre-clinical studies indicate that efficient retrovirus-mediated gene transfer into hematopoietic stem cells and progenitor cells can be achieved by co-localizing retroviral particles and target cells on specific adhesion domains of fibronectin. In this pilot study, we used this technique to transfer the human multidrug resistance 1 gene into stem and progenitor cells of patients with germ cell tumors undergoing autologous transplantation. There was efficient gene transfer into stem and progenitor cells in the presence of recombinant fibronectin fragment CH-296. The infusion of these cells was associated with no harmful effects and led to prompt hematopoietic recovery. There was in vivo vector expression, but it may have been limited by the high rate of aberrant splicing of the multidrug resistance 1 gene in the vector. Gene marking has persisted more than a year at levels higher than previously reported in humans.

Ex Vivo Expansion of Hematopoietic Stem and Progenitor Cells: Are We There Yet?

Ex vivo expansion of hematopoietic stem and progenitor cells is a very ambitious idea that would have major implications in the areas of stem cell transplantation and somatic gene therapy. However, successful ex vivo expansion has evaded and frustrated scientists for a number of years. The goal of ex vivo expansion is to induce cell division and proliferation of stem cells while maintaining their primary functional characteristic, namely, their ability to engraft and sustain long-term hematopoiesis. Only when a balance between these two requirements is reached can ex vivo expansion of stem cells be considered successful. Establishing such a balance has not been easy. However, many lessons have been learned along the way, and today we have a more profound understanding of the potential obstacles facing ex vivo expansion than we did only a few years ago. In this review, we discuss these obstacles and evaluate the current status of ex vivo expansion of stem and progenitor cells both from the perspective of basic stem cell biology and from the viewpoint of clinical utility of these cells in transplantation.

Chronic myelogenous leukaemia CD34+ cells exit G0/G1 phases of cell cycle more rapidly than normal marrow CD34+ cells

To investigate the mechanisms behind the leukaemic expansion of chronic myelogenous leukaemia (CML), we examined the cell cycle status and activation kinetics of purified subpopulations of CD34+ cells from normal and CML bone marrow (BM). Propidium iodide staining was used to assess cell cycle status of fresh cells or those stimulated with cytokines. Although the cell cycle status of fresh low‐density cells from CML and normal BM was similar, a larger percentage of CML CD34+ cells were cycling than those from normal BM. The HLA‐DR− compartment of CML CD34+ cells, a fraction enriched for normal, non‐leukaemic progenitors, contained a higher percentage of quiescent cells than the CD34+ HLA‐DR+ fraction. When the activation of CD34+ cells was examined in response to SCF or IL‐3 alone, or SCF+IL‐3+IL‐6, CML CD34+ cells exited G0/G1 more rapidly than normal CD34+ cells. Interestingly, although normal BM CD34+ cells failed to cycle in response to IL‐6 alone, or in the absence of exogenous cytokines, 30% of CML cells cycled under these conditions. No differences in the degree of apoptosis were documented among CML and normal CD34+ cells in these cultures. These data suggest that enhanced cell cycle activation of CML CD34+ cells, by either autocrine stimuli or via enhanced sensitivity to exogenous stimuli, may be partially responsible for the pronounced cellular expansion characteristic of CML.

Use of Merocyanine 540 for the Isolation of Quiescent, Primitive Human Bone Marrow Hematopoietic Progenitor Cells

Merocyanine 540 (MC540) is a membrane probe that inserts preferentially into loosely packed domains in the phospholipid bilayer of intact cells. Previous experiments have demonstrated that MC540 will bind to human bone marrow (BM) hematopoietic progenitor cells (HPC). Fractions of mononuclear BM cells expressing high MC540 fluorescence have been shown to be enriched for myeloid progenitors and cells residing in the S/G2 + M phases of the cell cycle. We rationalized that MC540 uptake could be used to distinguish between quiescent and metabolically active cells and, therefore, to fractionate normal and leukemic BM cells and normal mobilized peripheral blood (MPB) cells into functionally distinct groups of progenitors. BM and MPB cells were separated into fractions ranging in fluorescence from MC540Bright to MC540Dim. Cell cycle analysis of these fractions revealed that the MC540Dim fraction of normal and CML BM CD34+ cells constituted the most quiescent fraction, and the MC540Bright fractions from these cell types contained the most actively cycling cells. However, no differences in the percentage of cells in G/G1 were observed between MC540Bright and MC540Dim fractions of MPB CD34+ cells. To investigate if these cell cycle status differences translated into distinct functional properties, the hematopoietic potential of BM CD34+MC540Bright and CD34+MC540Dim cell fractions was analyzed in vitro in long-term BM cultures and limiting dilution analysis (LDA) assays. CD34+MC540Dim cells produced more total and committed progenitor cells in long-term cultures than did the CD34+MC540Bright fraction. The CD34+MC540Dim fraction also contained a 2-fold higher number of long-term hematopoietic culture-initiating cells (LTHCIC) than the CD34+MC540Bright fraction, as defined by LDA assays. These data demonstrate that MC540 can be a useful probe for the isolation of primitive HPC from some hematopoietic tissues and may assist in monitoring structural changes in the phospholipid bilayer during proliferation and differentiation of HPC.