Yolk platelets in artemia embryos: are they really storage sites of immature mitochondria?

We have used semi-quantitative polymerase chain reaction (PCR) technology to determine the mitochondrial DNA (mtDNA) content of yolk platelets isolated from embryos of the brine shrimp, Artemia franciscana, and ultrastructural analysis of yolk platelet formation to determine whether these organelles contain mitochondria as reported previously. Using six different isolation and purification protocols, we found one yolk platelet preparation to be devoid of mtDNA, while four yolk platelet preparations contained mtDNA ranging from 16.4 to 85 pg/10(6) yolk platelets. One preparation contained 600 pg mtDNA per 10(6) yolk platelets. Based on our PCR analyses, the mtDNA component of Artemia yolk platelets represented 0.16-4.5% of the total DNA isolated from the platelets. We calculated that Artemia yolk platelets contain, on average, approximately 1.78 molecules of mtDNA/platelet. Direct analysis of mtDNA in "free" mitochondria isolated from yolk platelet-free preparations of Artemia embryos and newly hatched larvae yielded 0.76-0.80 ng/animal. Based on these values, the mtDNA content of yolk platelets was approximately 0.2% of total mtDNA in Artemia embryos. Microscopic analysis of yolk platelet formation during oogenesis in Artemia failed to show the inclusion of mitochondria during the assemblage of yolk platelets. The "mitochondria-like" structures that appear in yolk platelets during their utilization lack the well defined inner and outer membranes characteristic of mitochondria making it unlikely that the yolk platelet inclusions are mitochondria. Our results from PCR technology and ultrastructure analysis demonstrate that mtDNA in yolk platelets of Artemia franciscana embryos is a minor component of the total mtDNA in the embryo, and they fail to support the notion that yolk platelets in Artemia are a major source of immature mitochondria for development.

Unique differentiation programs of human fetal liver stem cells shown both in vitro and in vivo in NOD/SCID mice.

Comparative measurements of different types of hematopoietic progenitors present in human fetal liver, cord blood, and adult marrow showed a large (up to 250-fold), stage-specific, but lineage-unrestricted, amplification of the colony-forming cell (CFC) compartment in the fetal liver, with a higher ratio of all types of CFC to long-term culture-initiating cells (LTC-IC) and a lower ratio of total (mature) cells to CFC. Human fetal liver LTC-IC were also found to produce more CFC in LTC than cord blood or adult marrow LTC-IC, and more of the fetal liver LTC-IC-derived CFC were erythroid. Human fetal liver cells regenerated human multilineage hematopoiesis in NOD/SCID mice with the same kinetics as human cord blood and adult marrow cells, but sustained a high level of terminal erythropoiesis not seen in adult marrow-engrafted mice unless exogenous human erythropoietin (Epo) was injected. This may be due to a demonstrated 10-fold lower activity of murine versus human Epo on human cells, sufficient to distinguish between a differential Epo sensitivity of fetal and adult erythroid precursors. Examination of human LTC-IC, CFC, and erythroblasts generated either in NOD/SCID mice and/or in LTC showed the types of cells and hemoglobins produced also to reflect their ontological origin, regardless of the environment in which the erythroid precursors were generated. We suggest that ontogeny may affect the behavior of cells at many stages of hematopoietic cell differentiation through key changes in shared signaling pathways.