Delayed myeloid engraftment following cord blood transplantation (CBT) is thought to result from inadequate numbers of progenitor cells in the graft and is associated with increased early transplant related morbidity and mortality. Novel culture strategies that increase the number of cord blood (CB) progenitors capable of rapid myeloid engraftment following CBT would allow more widespread use of this stem cell source for transplantation. Here we report development of a clinically relevant Notchmediated ex vivo expansion system for human CD34 + CB progenitors that results in a >100 fold increase in the absolute number of stem/progenitor cells, including those capable of enhanced repopulation in the marrow of immunodeficient NOD/SCID mice. Furthermore, when Notchmediated ex vivo expanded CB progenitors were infused in a clinical setting, rapid recovery of myeloid cells was achieved, demonstrating the first observation of rapid engraftment derived from ex vivo expanded stem/progenitor cells in humans.
Neuroblastoma cells in culture were used to detect sodium channel-specific marine toxins based on an end-point determination of mitochondrial dehydrogenase activity. The assay responds in a dose-dependent manner to ciguatoxins, brevetoxins, and saxitoxins, and delineates the toxic activity as either sodium channel enhancing or sodium channel blocking. The assay responds rapidly to sodium channel activating toxins, allowing dose dependent detection in 4 to 6 h. Brevetoxins can be detected at 250 pg, and purified ciguatoxins are detected in the low picogram and subpicogram levels. The results obtained from cell bioassay of ciguatoxic finfish extracts correlates with those obtained from mouse bioassays. Sodium channel blocking toxins can also be detected with an approximate sensitivity of 20 pg in 24 to 48 h. This cell-based technique is simple, sensitive, demonstrates potential as an alternative to animal testing for sodium channel activating and blocking toxins, and can be automated.
The unique oncogene carried by the McDonough strain of feline sarcoma virus (SM-FeSV), called v-fms, directs the synthesis of a set of related glycoproteins, called gP 180gag-fms, gp 140fms, and gp 120fms. We have prepared antibodies to these proteins and used indirect immunofluorescence techniques on viable SM-FeSV transformed cells to demonstrate that fms-specific determinants are expressed on the external surface. The fms-specific fluorescence co-localized with clathrin and was detectable in clathrin-coated pits and endocytotic vesicles. Two cell surface labeling methods indicated that gp140fms was the only fms-related protein on the cell surface. In view of the relationship between the erbB oncogene product and the epidermal growth factor receptor, and the fact that growth factor receptors utilize clathrin-coated pits in endocytosis, we believe the gp140fms transforming protein of SM-FeSV also could function as an analog of a growth factor receptor.
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