For decades it has been assumed that lethal irradiation in bone marrow transplantation experiments ablates the entire host hematopoietic system but preserves the host non-hematopoietic bone marrow stroma. This postulate is at the basis of transplantation chimera experiments in mice to test involvement of hematopoietic cells versus non-hematopoietic stroma. As BM-Macs support HSC niche homeostasis, we examined whether host-derived BM-Macs persist lethal irradiation and play a role in HSC engraftment. Recipient MacGreen mice (expressing GFP in myeloid cells under the control of Csf1r promoter) were lethally irradiated (11.5Gy) and transplanted with sorted syngeneic B6.SJL CD45.1+ Lin-Kit+Sca1+ sorted cells. Flow cytometry analyses of BM 2-30 weeks (wk) post-transplant confirmed more than 99% donor chimerism of monocytes and granulocytes validating ablation of recipient HSC. In contrast, GFP+CD11b+F4/80+CD169+VCAM-1+ERHR3+Ly6Gneg recipient BM-Macs were detected throughout the time-course. A 5.9 fold expansion of these recipient BM-Macs occurred between wk 2 and 5 ( from 45,000 to 270,000 cells/femur) post-transplant which coincided with increased number of phenotypic donor HSC (GFP-Lin-Kit+Sca1+CD48-CD150+). Host BM-Mac proliferation was cell autonomous in the absence of host HSC and granulocytes. Recipient Macs in spleen displayed different frequency and longevity kinetics that correlated with transient post-Tx splenic extramedullary haematopoiesis. In situ, GFP+F480+ recipient BM-Macs were enriched in perivascular microenvironments within both central BM and endosteal regions. These GFP+ host-derived macrophages persisted long-term forming 8.4% of BM macrophages 7months post-transplant. To evaluate the importance of these host-derived radiation-resistant macrophages, we selectively depleted recipient BM-Macs using CD169-DTR mice transplanted with syngeneic ubiquitous GFP+ HSC. Depletion of recipient CD169+ Macs abated engraftment of donor phenotypic HSC by 70% at 5 wk post-transplant and reduced BM reconstitution potential in competitive secondary transplants. In conclusion BM contains a myeloablation-resistant self-repopulating Mac subset that is necessary for efficient and/or sustained HSC BM engraftment following transplantation. Therefore interpretation of transplantation chimera experiments must take into account the persistence of this subset of host macrophages that support donor HSC engraftment.