We have measured the number of progenitor cells circulating in fetal (17-32 weeks of gestation), perinatal (36 weeks of gestation), and adult (30-50 years old) blood. The progenitor cells at each ontogenetic stage were also characterized in terms both of the minimal combinations of growth factors they required to form maximal numbers of colonies in vitro and of their self-replication potential, as measured by the number of secondary and tertiary progenitor cells each could generate. The number of progenitor cells circulating in fetal and perinatal blood can be measured by directly plating the unfractionated blood. In this assay, fetal blood contains half the number of progenitor cells detected in perinatal blood (18.0 +/- 16.4 versus 40.88 +/- 0.63, p < 0.01), and the number of progenitor cells in adult blood is below the level of detection of the assay (< 1/8 microliter of blood). To compare the number of progenitor cells in all three stages of human development, progenitor cell counts were performed on blood mononuclear cells enriched by density separation. In this case, the light density cell fractions from fetal and neonatal blood contained the same number of progenitor cells (300/10(5) cells), numbers that were 10-fold higher than those observed with adult blood (30/10(5) cells). Circulating fetal-neonatal erythroid and multipotential progenitor cells were found to differ from their adult counterparts in terms of their response to growth factors and their self-renewal ability. In fact, the number of cytokines required to observe maximal colony formation increased with the ontogenetic stage of the cells. No differences were found in the frequency of primary colonies containing progenitor cells or in the mean number of secondary progenitor cells per primary colony in cultures of fetal, neonatal, or adult blood. Differences between the three ontogenetic stages, however, were found with respect to the number of sequential replatings that were possible. In fact, although both secondary granulocyte-macrophage (GM) and mixed-cell colonies derived from fetal cells gave rise to tertiary colonies, only perinatal secondary mixed-cell colonies grew in tertiary cultures, and no growth was observed in tertiary cultures of adult cells. These results suggest that the greater amplification of progenitor cells observed in liquid culture of fetal/neonatal versus adult blood is due both to a higher proliferative capacity of neonatal progenitor cells (up to two replatings versus one) and to a higher frequency in these samples of mixed-cell colony-forming cells (CFC) (37.7 +/- 7.3 versus 2.0 +/- 0.7/10(5) light density cells, respectively). Because of the high numbers of progenitor cells circulating in the fetus, as well as their high proliferative capacity, it is predicted that if blood could be harvested directly in utero, fetal blood would be as good a source of stem cells for transplantation as perinatal placental/cord blood. Circulating fetal stem cells would, therefore, represent an ideal target for gene therapy and in utero autologous transplantation.