Because of their known myelopoietic activities, both interleukin (IL)-3 and IL-1 are often used in combination with other cytokines for in vitro (ex vivo) expansion of stem cells. We have investigated the effects of IL-3 and IL-1 on in vitro expansion of murine hematopoietic stem cells with long-term engraftment capabilities, using a highly purified progenitor population. Lineage-negative, Ly-6A/E+, c-kit+ bone marrow cells from male mice were cultured in suspension in the presence of stem cell factor, IL-6, IL-11, and erythropoietin with or without IL-3 or IL-1. Kinetic 200 units/ml; SCF, 100 ng/ml; IL-6, 100 ng/ml; Ep, 2 units/ml; 20 ng/ml; IL-la, 1 ng/ml;
Non-haemolytic transfusion reactions are the most common type of transfusion reaction and include transfusion-related acute lung injury, transfusion-associated circulatory overload, allergic reactions, febrile reactions, post-transfusion purpura and graft-versus- host disease. Although life-threatening anaphylaxis occurs rarely, allergic reactions occur most frequently. If possible, even mild transfusion reactions should be avoided because they add to patients' existing suffering. During the last decade, several new discoveries have been made in the field of allergic diseases and transfusion medicine. First, mast cells are not the only cells that are key players in allergic diseases, particularly in the murine immune system. Second, it has been suggested that immunologically active undigested or digested food allergens in a donor's blood may be transferred to a recipient who is allergic to these antigens, causing anaphylaxis. Third, washed platelets have been shown to be effective for preventing allergic transfusion reactions, although substantial numbers of platelets are lost during washing procedures, and platelet recovery after transfusion may not be equivalent to that with unwashed platelets. This review describes allergic transfusion reactions, including the above-mentioned points, and focusses on their incidence, pathogenesis, laboratory tests, prevention and treatment.
We have used a two-step clonal culture system to unequivocally demonstrate that individual primitive lymphohemopoietic progenitor cells have the capacity for differentiation along either the myeloid or the B-lymphoid lineage. Highly enriched murine marrow cells were plated individually in culture by micromanipulation in the presence of pokeweed mitogen-stimulated spleen cell conditioned medium, erythropoietin, steel factor (SF), and interleukin (IL) 7. Forty-five percent of the single cells formed primary colonies expressing multiple hemopoietic lineages. When aliquots from individual colonies were replated in secondary methyl cellulose culture containing SF and IL-7, 41% of the primary colonies gave rise to lymphocyte colonies. Cells of the lymphocyte colonies were blast-like and B220+, sIg-, Mac-l1, Gr-l-, Ly-l1, L3T4-, Ly-2-, and CD3-. Thirty to 70% of the cells were Thy-l+.,u-chain mRNA was detected in most of the cells by in situ hybridization with an antisense RNA probe. When lymphocyte colonies derived from a single cell were pooled and individually injected into scid mice, donor-type IgM was measurable in the serum of mice and spleens contained donor-type B cells. We then carried out initial screening of growth factors to identify growth factors that might replace pokeweed mitogenstimulated spleen cell conditioned medium in the primary culture. Combinations of two factors that included SF plus IL-6, IL-ll, or granulocyte colony-stimulating factor were all effective in the primary culture in the maintenance of the B-lymphoid potential. Interestingly, IL-3 could neither replace nor act synergistically with SF to support the lymphoid potential of the primary cultures. Our observations demonstrate that many primitive progenitors previously believed to be myeloidcommitted also possess B-lymphoid potential. This culture system should prove valuable for elucidation of the mechanisms regulating early stages of lymphohemopoiesis.The existence of pluripotent lymphohemopoietic stem cells was postulated long ago through observation of reconstitution of patients after bone marrow transplantation and through careful analysis of transplantation in experimental animals. More recently, retroviral labeling of individual hemopoietic progenitors has clearly demonstrated the existence of cellular precursors common to all of the blood cell lineages, both myeloid and lymphoid. However, despite all of this in vivo evidence, it has not yet been possible to detect and quantitate the existence of these pluripotent cells through in vitro culture. Clonal cell culture assays have been available for many years for analysis of committed myeloid progenitors. Long-term suspension culture systems have been devised that can be used to maintain exclusively myeloid or lymphoid development, depending on the conditions. Recently described lymphocyte colony assay systems appear also to support the development of pre-B and B cells but not earlier precursors (1-3). Despite considerable investigation of the growth factor requirements of im...
We recently developed a two-step methyl cellulose culture system for murine lymphohemopoietic progenitors that are capable of differentiation along the myeloid and B-lymphoid lineages. In this system, two-factor combinations, which include steel factor plus interleukin (IL) 6, IL-ll, or granulocyte colony-stimulating factor effectively supported the lymphomyeloid potential of primary colonies. Interestingly, IL-3 could neither replace nor act synergistically with steel factor in maintaining the B-lymphoid potential of the primary colonies although the frequency of colony formation was the same with IL-3 and steel factor. We now report that addition of IL-3 or IL-la to a permissive system suppresses the B-lymphoid potential of primitive progenitor cells in primary culture in dose-dependent fashion. In vivo transfer of the primary colonies to scid mice confirmed the suppressive effects of IL-3 and IL-la. In addition, IL-la inhibited pre-B-cell colony formation in the secondary culture. Once pre-B-cell colonies had formed in secondary culture, neither factor affected the proliferation of the pre-B cells. These results suggest negative regulatory roles for IL-3 and IL-la in early stages of B lymphopoiesis.
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