OBJECTIVE: Ionizing radiation-induced myeloablation can be rescued via bone marrow transplantation (BMT) or administration of cytokines if given within 2 hours after radiation exposure. There is no evidence for the existence of soluble factors that can rescue an animal after a lethal dose of radiation when administered several hours postradiation. We established a system that could test the possibility for the existence of soluble factors that could be used more than 2 hours postirradiation to rescue animals. MATERIALS AND METHODS: Animals with an implanted TheraCyte immunoisolation device (TID) received lethal-dose radiation and then normal bone marrow Lin- cells were loaded into the device (thereby preventing direct interaction between donor and recipient cells). Animal survival was evaluated and stem cell activity was tested with secondary bone marrow transplantation and flow cytometry analysis. Donor cell gene expression of five antiapoptotic cytokines was examined. RESULTS: Bone marrow Lin- cells rescued lethally irradiated animals via soluble factor(s). Bone marrow cells from the rescued animals can rescue and repopulate secondary lethally irradiated animals. Within the first 6 hours post-lethal-dose radiation, there is no significant change of gene expression of the known radioprotective factors TPO, SCF, IL-3, Flt-3 ligand, and SDF-1. CONCLUSION: Hematopoietic stem cells can be protected in lethally irradiated animals by soluble factors produced by bone marrow Lin- cells.
OBJECTIVE: Ionizing radiation-induced myeloablation can be rescued via bone marrow transplantation (BMT) or administration of cytokines if given within 2 hours after radiation exposure. There is no evidence for the existence of soluble factors that can rescue an animal after a lethal dose of radiation when administered several hours postradiation. We established a system that could test the possibility for the existence of soluble factors that could be used more than 2 hours postirradiation to rescue animals. MATERIALS AND METHODS: Animals with an implanted TheraCyte immunoisolation device (TID) received lethal-dose radiation and then normal bone marrow Lin- cells were loaded into the device (thereby preventing direct interaction between donor and recipient cells). Animal survival was evaluated and stem cell activity was tested with secondary bone marrow transplantation and flow cytometry analysis. Donor cell gene expression of five antiapoptotic cytokines was examined. RESULTS: Bone marrow Lin- cells rescued lethally irradiated animals via soluble factor(s). Bone marrow cells from the rescued animals can rescue and repopulate secondary lethally irradiated animals. Within the first 6 hours post-lethal-dose radiation, there is no significant change of gene expression of the known radioprotective factors TPO, SCF, IL-3, Flt-3 ligand, and SDF-1. CONCLUSION: Hematopoietic stem cells can be protected in lethally irradiated animals by soluble factors produced by bone marrow Lin- cells.
Authors: Claudia Wrzesinski; Chrystal M Paulos; Luca Gattinoni; Douglas C Palmer; Andrew Kaiser; Zhiya Yu; Steven A Rosenberg; Nicholas P Restifo Journal: J Clin Invest Date: 2007-02 Impact factor: 14.808
Authors: Miguel F Diaz; Paulina D Horton; Sandeep P Dumbali; Akshita Kumar; Megan Livingston; Max A Skibber; Amina Mohammadalipour; Brijesh S Gill; Songlin Zhang; Charles S Cox; Pamela L Wenzel Journal: Sci Rep Date: 2020-12-17 Impact factor: 4.379
Authors: Somaiah Chinnapaka; Katherine S Yang; Yasamin Samadi; Michael W Epperly; Wen Hou; Joel S Greenberger; Asim Ejaz; J Peter Rubin Journal: Stem Cells Transl Med Date: 2021-03-16 Impact factor: 6.940