Figure 3
Figure 3. Human hematopoietic engraftment potential in NOD/SCID mice is restricted to CD34+ UCB cells expressing BB9. (A) Sort regions used for isolation of CD34+BB9+ () and CD34+BB9− (◆) cells. (B and C) Representative examples displaying flow cytometric analysis of bone marrow from NOD/SCID recipients of CD34+BB9− and CD34+BB9+ UCB, respectively. Human (Hu45) and murine (Mu45) hematopoietic cells are identified by species-specific anti-CD45 immunolabeling. (D) Proportion of human CD45+ cells in individual animals that received a transplant of 2 × 106 unfractionated mononuclear cells (MNCs), and between 1 to 2 × 105 CD34+BB9− or CD34+BB9+ cells. — represents the median percentage of human CD45+ cells of each group. (E) Representative example of multilineage human hematopoietic engraftment in an animal that received a transplant of 1× 105 CD34+BB9+ cells. Both myeloid (CD11b, CD14, CD15) and B-lymphoid (CD19, CD20) progeny are evident.

Human hematopoietic engraftment potential in NOD/SCID mice is restricted to CD34+ UCB cells expressing BB9. (A) Sort regions used for isolation of CD34+BB9+ () and CD34+BB9 (◆) cells. (B and C) Representative examples displaying flow cytometric analysis of bone marrow from NOD/SCID recipients of CD34+BB9 and CD34+BB9+ UCB, respectively. Human (Hu45) and murine (Mu45) hematopoietic cells are identified by species-specific anti-CD45 immunolabeling. (D) Proportion of human CD45+ cells in individual animals that received a transplant of 2 × 106 unfractionated mononuclear cells (MNCs), and between 1 to 2 × 105 CD34+BB9 or CD34+BB9+ cells. — represents the median percentage of human CD45+ cells of each group. (E) Representative example of multilineage human hematopoietic engraftment in an animal that received a transplant of 1× 105 CD34+BB9+ cells. Both myeloid (CD11b, CD14, CD15) and B-lymphoid (CD19, CD20) progeny are evident.

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