Purification of repopulating hemopoietic cells based on binding of biotinylated Kit ligand.

To characterize Kit expressing mouse bone marrow (BM) cells, and to determine their contribution to short- and long-term repopulation of the hemopoietic system of irradiated recipients, we have purified Kit+ BM cells by flow cytometry. A high level of Kit expression was detectable on 1-2% of BM cells after staining with biologically active biotinylated Kit ligand (KL) or with anti-Kit antibodies (ACK-2). Compared to unfractionated BM, the Kit+ fractions were enriched for immature hemopoietic cells, as shown by morphological differentiation, in vitro culture, and spleen colony formation. Enrichment of colony-forming cells was higher in biotin-KL+ than ACK-2+ fractions. Colony-forming cells were not found in the Kit- subsets. To study the hemopoietic repopulation capacity of the Kit+ and Kit- cells, serial dilutions of the sorted fractions were transplanted into irradiated mice, and peripheral blood of these recipients was monitored regularly for the presence of donor-derived cells during a 1 year period. Nucleated blood cell repopulation by male donor cells in female recipients was assessed using a Y-chromosome specific DNA probe; erythroid repopulation by normal donor cells in W/Wv recipients was examined flow cytometrically by measuring the forward light scatter of donor- and host-type erythrocytes. A 25- to 100-fold enrichment of long-term repopulating ability in the sorted Kit+ fractions showed that Kit+ cells are capable of reconstitution of circulating erythrocytes and nucleated blood cells after BM transplantation. Transient repopulation of the red blood cell lineage was observed after transplantation of Kit- cells. Detection of donor-derived nucleated cells 1 year after transplantation showed that Kit+ cells contributed to donor-type repopulation of bone marrow, spleen and thymus. Our data demonstrate that isolation of BM cells on the basis of Kit expression is a useful addition to the methods that are commonly applied in stem cell enrichment protocols.

Identification of hematopoietic stem cell subsets on the basis of their primitiveness using antibody ER-MP12.

Monoclonal antibody ER-MP12 defines a novel antigen on murine hematopoietic stem cells. The antigen is differentially expressed by different subsets in the hematopoietic stem cell compartment and enables a physical separation of primitive long-term repopulating stem cells from more mature multilineage progenitors. When used in two-color immunofluorescence with ER-MP20 (anti-Ly-6C), six subpopulations of bone marrow (BM) cells could be identified. These subsets were isolated using magnetic and fluorescence-activated cell sorting, phenotypically analyzed, and tested in vitro for cobblestone area-forming cells (CAFC) and colony-forming units in culture (CFU-C; M/G/E/Meg/Mast). In addition, they were tested in vivo for day-12 spleen colony-forming units (CFU-S-12), and for cells with long-term repopulating ability using a recently developed alpha-thalassemic chimeric mouse model. Cells with long-term repopulation ability (LTRA) and day-12 spleen colony-forming ability appeared to be exclusively present in the two subpopulations that expressed the ER-MP12 cell surface antigen at either an intermediate or high level, but lacked the expression of Ly-6C. The ER-MP12med20- subpopulation (comprising 30% of the BM cells, including all lymphocytes) contained 90% to 95% of the LTRA cells and immature day-28 CAFC (CAFC-28), 75% of the CFU-S-12, and very low numbers of CFU-C. In contrast, the ER-MP12hi20- population (comprising 1% to 2% of the BM cells, containing no mature cells) included 80% of the early and less primitive CAFC (CAFC-5), 25% of the CFU-S-12, and only 10% of the LTRA cells and immature CAFC-28. The ER-MP12hi cells, irrespective of the ER-MP20 antigen expression, included 80% to 90% of the CFU-C (day 4 through day 14), of which 70% were ER-MP20- and 10% to 20% ER-MP20med/hi. In addition, erythroblasts, granulocytes, lymphocytes, and monocytes could almost be fully separated on the basis of ER-MP12 and ER-MP20 antigen expression. Functionally, the presence of ER-MP12 in a long-term BM culture did not affect hematopoiesis, as was measured in the CAFC assay. Our data demonstrate that the ER-MP12 antigen is intermediately expressed on the long-term repopulating hematopoietic stem cell. Its level of expression increases on maturation towards CFU-C, to disappear from mature hematopoietic cells, except from B and T lymphocytes.

Selective advantage of normal erythrocyte production after bone marrow transplantation of alpha-thalassemic mice.

Anemia resulting from alpha-thalassemia in mice was corrected by transplantation of normal bone marrow cells following sublethal total body irradiation, resulting in partial hematopoietic chimerism with a preponderance of normal peripheral blood red cells. Peripheral blood red cell chimerism in recipients of graded numbers of bone marrow cells from sex-mismatched donors, determined by cytometric analysis, was directly compared with immature hematopoietic cell (CFU-S) chimerism and peripheral blood white cell chimerism. The latter two were assessed by fluorescent in situ hybridization with a murine Y-chromosome-specific probe. Peripheral blood white cell chimerism consistently corresponded with immature hematopoietic cell chimerism, emphasizing the selective advantage of normal red cell production in partially chimeric alpha-thalassemic mice.

Correction of murine beta-thalassemia by partial bone marrow chimerism: selective advantage of normal erythropoiesis.

beta-Thalassemic mice were transplanted with normal congeneic BM cells after sublethal total body irradiation, which resulted in partial RBC chimerism and correction of anemia. Enumeration of donor-type early hemopoietic progenitor cells (CFU-S) demonstrated that the correction of anemia originated from a minority of normal immature BM cells. It is concluded that successful BMT in beta-thalassemia does not necessarily require ablation of endogenous BM.

Compensatory splenic hemopoiesis in beta-thalassemic mice.

beta-Thalassemic mice, homozygous for the deletion of the beta major-globin gene, were investigated for compensatory hemopoiesis in bone marrow and spleen. Apart from characteristic severe anemia, these mice have a marked granulocytosis, monocytosis and lymphocytosis. A large compensatory expansion of late (CFU-E) erythroid progenitor cells was demonstrated, predominantly in the spleen. Immature hemopoietic cells (CFU-S) were also expanded, as were early progenitor cells of erythroid (BFU-E), as well as granulocyte/macrophage (GM-CFU) and megakaryocytic (CFU-Meg) lineages. It is concluded that the persistent erythropoietic stress results in a selective expansion of immature hemopoietic cells and inappropriate production of nonerythroid blood cells from excess production of progenitor cells.