Localized bone marrow transplantation leads to skin allograft acceptance in nonmyeloablated recipients: comparison of intra-bone marrow and isolated limb perfusion

Mechanisms of Tolerance Induction by Hematopoietic Chimerism: The Immune Perspective

Hematopoietic chimerism is one of the effective approaches to induce tolerance to donor‐derived tissue and organ grafts without administration of life‐long immunosuppressive therapy. Although experimental efforts to develop such regimens have been ongoing for decades, substantial cumulative toxicity of combined hematopoietic and tissue transplants precludes wide clinical implementation. Tolerance is an active immunological process that includes both peripheral and central mechanisms of mutual education of coresident donor and host immune systems. The major stages include sequential suppression of early alloreactivity, establishment of hematopoietic chimerism and suppressor cells that sustain the state of tolerance, with significant mechanistic and temporal overlap along the tolerization process. Efforts to devise less toxic transplant strategies by reduction of preparatory conditioning focus on modulation rather than deletion of residual host immunity and early reinstitution of regulatory subsets at the central and peripheral levels. Stem Cells Translational Medicine2017;6:700–712

Engineering of bone marrow cells with fas-ligand protein-enhances donor-specific tolerance to solid organs

Effective immunomodulation to induce tolerance to tissue/organ allografts is attained by infusion of donor lymphocytes endowed with killing capacity through ectopic expression of a short-lived Fas-ligand (FasL) protein. The same approach has proven effective in improving hematopoietic stem and progenitor cell engraftment. This study evaluates the possibility of substitution of immune cells for bone marrow cells (BMC) to induce FasL-mediated tolerance to solid organ grafts. Expression of FasL protein on BMC increased the survival of simultaneously grafted vascularized heterotopic cardiac grafts to 90%, as compared to 30% in recipients of naïve BMC. Similar results were obtained for skin allografts implanted into radiation chimeras at 1 week after bone marrow transplantation. Further reduction of preparative conditioning to busulfan resulted in acceptance of donor skin implanted at 2 weeks after transplantation of naïve and FasL-coated BMC, whereas third-party grafts were acutely rejected. The levels of donor chimerism were in the range of 0.7% to 12% at the time of skin grafting, with higher levels in recipients of FasL-coated BMC. It is concluded that FasL-mediated abrogation of alloimmune responses can be effectively attained with BMC. There is no threshold of donor chimerism, but tolerance to solid organs evolves during the process of donor-host mutual acceptance.

Consideration of strategies for hematopoietic cell transplantation

Bone marrow transplantation has been adoptively transferred from oncology to the treatment of autoimmune disorders. Along with extension of prevalent transplant-related concepts, the assumed mechanism that arrests autoimmunity involves elimination of pathogenic cells and resetting of immune homeostasis. Similar to graft versus tumor (GVT) reactivity, allogeneic transplants are considered to provide a better platform of immunomodulation to induce a graft versus autoimmunity reaction (GVA). It is yet unclear whether recurrence of autoimmunity in both autologous and allogeneic settings reflects relapse of the disease, transplant-associated immune dysfunction or insufficient immune modulation. Possible causes of disease recurrence include reactivation of residual host pathogenic cells and persistence of memory cells, genetic predisposition to autoimmunity and pro-inflammatory characteristics of the target tissues. Most important, there is little evidence that autoimmune disorders are indeed abrogated by current transplant procedures, despite reinstitution of both peripheral and thymic immune homeostasis. It is postulated that non-specific immunosuppressive therapy that precedes and accompanies current bone marrow transplant strategies is detrimental to the active immune process that restores self-tolerance. This proposition refocuses the need to develop strategies of immunomodulation without immunosuppression.

Maintenance of donor-specific chimerism despite osteopontin-associated bone fibrosis in a vascularized bone marrow transplantation model

BACKGROUND

The role of vascularized bone allografting is not established in plastic and reconstructive surgery. The authors evaluated the contribution by osteopontin to fibrosis of allografted bone in a vascularized bone marrow transplantation model across a major histocompatibility complex barrier.

METHODS

Thirty-six transplantations were performed between Brown Norway (RT1 n) donors and Lewis (RT1 l) recipients divided into three groups: group 1, isografts between Lewis rats (n = 12); group 2, allografts without treatment (n = 8); and group 3, allografts under a 7-day alphabeta-T-cell receptor/cyclosporine protocol (n = 16). Flow cytometry assessed the presence of chimerism for donor major histocompatibility complex class I (RT1 n) antigens. Immunostaining was used to determine osteopontin expression in grafted and recipient bone, and histologic examination was used to assess bone architecture.

RESULTS

Early engraftment of donor bone marrow cells (RT1 n) into the recipient bone marrow compartment was achieved at posttransplantation day 7. This corresponded with osteopontin expression restricted to the endosteum of trabecular bone and was associated with the preservation of hematopoietic cells within donor bone. Cell migration between donor and recipient bone marrow compartments was confirmed by the presence of recipient cells (RT1 l) within the allografted bone and donor-origin cells (RT1 n) within the recipient bone. At posttransplantation day 63, osteopontin expression within allografted bone was associated with allograft bone fibrosis and lack of hematopoietic properties. In contrast, the recipient's contralateral bone demonstrated a highly localized osteopontin expression pattern within the endosteum and active hematopoiesis with the presence of donor-specific (RT1 n) cells and correlated with chimerism maintenance.

CONCLUSIONS

These results confirm that despite up-regulation of osteopontin expression and fibrosis of allografted bone, vascularized bone marrow transplantation resulted in efficient engraftment of donor cells into the recipient's bone marrow compartment, leading to chimerism maintenance.

Hematopoietic stem cell engraftment and seeding permits multi-lymphoid chimerism in vascularized bone marrow transplants

Vascularized bone marrow transplantation (VBMT) across a MHC barrier under a 7-day alphabeta-TCR mAb and CsA protocol facilitated multiple hematolymphoid chimerism via trafficking of the immature (CD90) bone marrow cells (BMC) between donor and recipient compartments. Early engraftment of donor BMC [BN(RT1(n))] into the recipient BM compartment [LEW(RT1(l))] was achieved at 1 week posttransplant and this was associated with active hematopoiesis within allografted bone and correlated with high chimerism in the hematolymphoid organs. Two-way trafficking between donor and recipient BM compartments was confirmed by the presence of recipient MHC class I cells (RT1(l)) within the allografted bone up to 3 weeks posttransplant. At 10 weeks posttransplant, decline of BMC viability in allografted bone corresponded with bone fibrosis and lack of hematopoiesis. In contrast, active hematopoiesis was present in the recipient bone as evidenced by the presence of donor-specific immature (CD90/RT1(n)) cells, which correlated with chimerism maintenance. Clonogenic activity of donor-origin cells (RT1(n)) engrafted into the host BM compartment was confirmed by colony-forming units (CFU) assay. These results confirm that hematolymphoid chimerism is developed early post-VBMT by T-cell lineage and despite allografted bone fibrosis chimerism maintenance is supported by B-cell linage and active hematopoiesis of donor-origin cells in the host BM compartment.

Donor–origin cell engraftment after intraosseous or intravenous bone marrow transplantation in a rat model

We compared the effects of intraosseous BMT with those of standard i.v. BMT on the efficacy on donor-cell engraftment into the BM and lymphoid organs across an MHC barrier in rats. Twenty-four intraosseous and 24 i.v. BMTs were performed from 48 ACI (RT1(a)) donors to 48 Lewis (RT1(l)) recipients. Each transplant group received either intraosseous or i.v. BMT. Groups I and II served as controls without immunosuppression (n=16); groups III and IV received cyclosporine monotherapy (n=16); and V and VI received alphabeta-TCR monoclonal antibody and cyclosporine A (alphabeta-TCR/CsA) for 7 days (n=16). In each group, four rats received 35 x 10(6) transplanted bone marrow cells (BMCs) and four received 70 x 10(6) cells. All animals survived without GVHD. Mean (+/-s.d.) donor-cell engraftment into BM of recipients after intraosseous BMT was 7.9% (+/-1.3%) in recipients receiving alphabeta-TCR-CsA and 70 x 10(6) BMCs, and 4.2% (+/-1.4%) in recipients after i.v. transplantation. The seeding efficacy of donor cells into lymphoid tissue was greater after intraosseous BMT and alphabeta-TCR-CsA than after standard i.v. transplantation. In our model, intraosseous BMT facilitated donor-cell engraftment under short-term immunodepletive alphabeta-TCR/CsA protocol, which resulted in a temporary state of immune unresponsiveness.

Analyses of very early hemopoietic regeneration after bone marrow transplantation: comparison of intravenous and intrabone marrow routes

In bone marrow transplantation (BMT), bone marrow cells (BMCs) have traditionally been injected intravenously. However, remarkable advantages of BMT via the intra-bone-marrow (IBM) route (IBM-BMT) over the intravenous route (IV-BMT) have been recently documented by several laboratories. To clarify the mechanisms underlying these advantages, we analyzed the kinetics of hemopoietic regeneration after IBM-BMT or IV-BMT in normal strains of mice. At the site of the direct injection of BMCs, significantly higher numbers of donor-derived cells in total and of c-kit(+) cells were observed at 2 through 6 days after IBM-BMT. In parallel, significantly higher numbers of colony-forming units in spleen were obtained from the site of BMC injection. During this early period, higher accumulations of both hemopoietic cells and stromal cells were observed at the site of BMC injection by the IBM-BMT route. The production of chemotactic factors, which can promote the migration of a BM stromal cell line, was observed in BMCs obtained from irradiated mice as early as 4 hours after irradiation, and the production lasted for at least 4 days. In contrast, sera collected from the irradiated mice showed no chemotactic activity, indicating that donor BM stromal cells that entered systemic circulation cannot home effectively into recipient bone cavity. These results strongly suggest that the concomitant regeneration of microenvironmental and hemopoietic compartments in the marrow (direct interaction between them at the site of injection) contributes to the advantages of IBM-BMT over IV-BMT. Disclosure of potential conflicts of interest is found at the end of this article.

Chimerism induction in vascularized bone marrow transplants augmented with bone marrow cells

Composite tissue allografts (CTAs) are currently accepted in the clinic; however, long-term immunosuppression is still needed for allograft survival. The presence of donor-specific chimerism may induce tolerance. Thirty-six vascularized bone marrow transplantation (VBMT) allotransplantation were performed across MHC barrier under short-term protocol of 7-day alphabeta-TCRmAb and Cyclosporin A therapy to determine the efficacy of VBMT alone and VBMT augmented with donor bone marrow transplantation (BMT) in chimerism induction. Flow cytometry analysis revealed that VBMT supported with donor BMT directly into the bone resulted in chimerism augmentation and maintenance compared to VBMT. In vivo and in vitro tolerance testing showed prolonged survival of donor skin graft up to 35 days and moderate reactivity in MLR assay that suggests only tolerance induction. Transplantation of vascularized bone without chronic immunosuppression provides a substantial source of bone marrow cells, leading to the development of stable donor-specific chimerism.

The tale of early hematopoietic cell seeding in the bone marrow niche

Since introduction of the notion of a "niche" that hosts engraftment and activity of hematopoietic cells, there is a massive effort to discover its structure and decipher its function. Our understanding of the niche is continuously changing with reinterpretation of traditional concepts and apprehension of new insights into the biology of hematopoietic cell homing, seeding, and engraftment. Here we discuss some of the early events in hematopoietic stem cell seeding and engraftment and propose a perspective based on visualization of labeled bone marrow cells in real time in vivo. Primary seeding of hematopoietic cells in the bone marrow niches evolves as a complex and dynamic process; however, it follows discrete topological and chronological patterns. Initial seeding occurs on the endosteal surface of the marrow, which includes heterogeneous niches for primary seeding. Several days after transplantation the endosteal niches become more restrictive, hosting primarily mitotically quiescent cells, and gradual centripetal migration is accompanied by engagement in proliferation and differentiation. The hematopoietic niches evolve as heterogeneous three-dimensional microenvironments that are continuously changing over time.

Bone marrow-induced tolerance in the era of pancreas and islets transplantation

Enormous progress has been made in the field of solid organ adaptation recently because of the improvement in immunosuppression. Although powerful immunosuppressive drugs decrease the rate of acute rejection significantly, the long-term functional graft survival and tolerance induction remains poor. Chronic rejection is the main cause of graft failure. An electronic search was performed for articles on chimerism, tolerance, and immunologic perspectives of islet and pancreas transplantation along with referrals to our experience. Infusion of donor bone marrow-derived cells to create a chimeric state continue to be tested in clinical protocols intended to induce specific immunologic tolerance. The proposed mechanisms of immunologic engagement and the emergence of a tolerant state through mixed chimerism include central depletion of alloreactive cells, induction of T-cell anergy, and generation of suppressor cells by interactions between donor and host cells. In this setting, depletion of recipient T cells by different strategies and subsequent repopulation by donor hematopoietic cells after donor bone marrow infusion are prerequisites for tolerance induction. Many efforts have aimed to establish mixed chimerism along with tolerance in solid organ transplantation including pancreas and islets to facilitate engraftment. A review of the more important advances in the field and the future prospects combined with our experience to induce tolerance in the clinic and the laboratory is presented in this article.

Donor bone marrow transplantation: chimerism and tolerance

Infusion of donor bone marrow (DBM)-derived cells continue to be tested in clinical protocols intended to induce specific immunologic tolerance. Central clonal deletion of donor-specific alloreactive cells associated with mixed chimerism reliably produced long-term graft tolerance. In this setting, depletion of recipient T cells by antilymphocyte antibodies and subsequent repopulation by donor hematopoietic cells after donor bone marrow infusion (DBMI) are prerequisites for tolerance induction. Major advances have been made in animal models and in pilot clinical trials and the key questions with the future perspectives are presented in this article.

Enhancement of allogeneic hematopoietic stem cell engraftment and prevention of GVHD by intra-bone marrow bone marrow transplantation plus donor lymphocyte infusion

We examined the effect of intra-bone marrow (IBM)-bone marrow transplantation (BMT) in conjunction with donor lymphocyte infusion (DLI) on the engraftment of allogeneic bone marrow cells (BMCs) in mice. Recipients that had received 6 Gy of radiation completely rejected donor BMCs, even when IBM-BMT was carried out. However, when BMCs were IBM injected and donor peripheral blood mononuclear cells (PBMNCs) were simultaneously injected intravenously (DLI), donor cell engraftment was observed 7 days after BMT and complete donor chimerism continued thereafter. It is of interest that the cells of recipient origin did not recover, and that the hematolymphoid cells, including progenitor cells (Lin-/c-kit+ cells) in the recipients, were fully reconstituted with cells of donor origin. The cells in the PBMNCs responsible for the donor BMC engraftment were CD8+. Recipients that had received 6 Gy of radiation, IBM-BMT, and DLI showed only a slight loss of body weight, due to radiation side effects, and had no macroscopic or microscopic symptoms of graft-versus-host disease. These findings suggest that IBM-BMT in conjunction with DLI will be a valuable strategy for allogeneic BMT in humans.

Intra–bone marrow injection of bone marrow and cord blood cells: an alternative way of transplantation associated with a higher seeding efficiency

OBJECTIVE

Intravenous (IV) injection is currently the normal method for transplanting hematopoietic cells. However, the problem of seeding efficiency and homing is relevant especially when a limited number of stem cells is available. Intra-bone marrow (IBM) injection of bone marrow cells (BMCs) may overcome this problem.

MATERIALS AND METHODS

Irradiated (750 cGy) C57BL/6J mice were transplanted with 1 x 10(5) BMCs harvested from transgenic mice expressing an enhanced version of the green fluorescent protein (EGFP+) via IBM or with 1 x 10(6) EGFP+ BMCs via IV. Irradiated (320 cGy) NOD/SCID mice were transplanted with 1 x 10(6) human cord blood (CB) cells via IBM or with 1 x 10(7) human CB cells via IV.

RESULTS

In C57BL/6J mice after 90 days, the fraction of EGFP+ cells harvested was 37% and 53% in IV-treated and IBM-treated (contralateral tibia and femur in the IBM) mice, respectively: the expansion folds were 114 and 1760, respectively. In NOD/SCID mice, the percentages of CD45+ cells and CD45+/CD34+ cells were, at 30 days, 3.3% and 0.3% in IV-treated mice, and 4.4% and 1.1% in IBM-treated mice. At 60 days, the percentages of CD45+ cells and CD45+/CD34+ cells were 2.1% and 0.3% in IV-treated mice and 1.4% and 0.4% in IBM-treated mice. At day 90 the percentages of CD45+ cells and CD45+/CD34+ cells were 3% and 0.3% in IV-treated mice and 2.3% and 0.4% in IBM-treated mice.

CONCLUSION

Our data demonstrate that IBM transplantation is associated with a seeding efficiency 15 times greater than IV transplantation. IBM transplantation may improve the results of transplant and may be useful in several settings: 1) when a limited number of hematopoietic progenitors are available; and 2) in experiments aiming to place in the bone marrow stem cells of other lineages (CNS, muscle, etc.).

A novel strategy for allogeneic stem cell transplantation: perfusion method plus intra–bone marrow injection of stem cells

Using long bones of cynomolgus monkeys, we have recently developed a new "Perfusion Method (PM)" for harvesting bone marrow cells (BMCs) while minimizing the contamination of BMCs with T cells from the peripheral blood. When thus collected BMCs, which contain not only pluripotent hemopoietic stem cells (P-HSCs) but also mesenchymal stem cells (MSCs), are directly injected into the bone marrow cavity of recipients (intra-bone marrow BMT: "IBM-BMT"), the donor-derived hemopoietic cells quickly recover even when the radiation doses used as the conditioning regimen are reduced. Recipient mice, rats, and even monkeys show neither graft-vs-host disease (GVHD) nor graft failure. In this article, we discuss why this new method (PM+IBM-BMT) may become a valuable strategy for allogeneic stem cell (both P-HSC and MSC) transplantation.

Cardiac allograft acceptance after localized bone marrow transplantation by isolated limb perfusion in nonmyeloablated recipients

Donor-specific tolerance to cardiac grafts may be induced by hematopoietic chimerism. This study evaluates the potential of localized bone marrow transplantation (BMT) performed by isolated limb (IL) perfusion to induce tolerance to secondary cardiac grafts without myeloablative conditioning. BALB/c recipients (H2d) preconditioned with lethal and sublethal doses of busulfan were injected i.v. and IL with 10(7) whole bone marrow cells (wBMCs) from B10 donors (H2(b)). Two hours after IL infusion of PKH-labeled wBMCs into myeloablated hosts, there were few labeled cells in the host peripheral blood (p < 0.001 versus i.v.) and femurs of the infused limb contained 57% +/- 7% PKH-labeled blasts (p < 0.001 versus 8% +/- 0.6% after i.v.). Femurs of the noninfused limbs contained 60-70 PKH-labeled blasts (p < 0.001 versus i.v.-BMT) after 2 days and 47% +/- 5% of 0.32 x 10(7) donor cells (p < 0.001 versus 78% +/- 4% of 1.2 x 10(7) donor cells in infused femurs) after 4 weeks. The survival rates of myeloablated hosts were 90% and 80% after i.v. and IL infusion, respectively, and the chimeras had 78%-84% donor peripheral blood cells. In recipients conditioned with 35 mg/g busulfan, the levels of donor chimerism in peripheral blood were 33% +/- 4% and 21% +/- 4% at 3 weeks after i.v.- and IL-BMT, respectively. Transplantation of donor-matched (H2(b)) secondary vascularized hearts in these chimeras after 3 weeks resulted in graft survival for periods exceeding 8 weeks, while third-party (H2(k)) allografts were acutely rejected (p < 0.001 versus H2(b)). These data indicate that IL perfusion is a reliable alternative procedure for establishment of hematopoietic chimerism and donor-specific tolerance without myeloablative conditioning.

The topologic and chronologic patterns of hematopoietic cell seeding in host femoral bone marrow after transplantation

The early stages of homing, seeding, and engraftment of hematopoietic stem and progenitor cells are poorly characterized. We have developed an optical technique that allows in vivo tracking of transplanted, fluorescent-tagged cells in the host femurs. In this study we used fluorescence microscopy to monitor the topologic and chronologic patterns of hematopoietic cell seeding in the femoral bone marrow (BM) of mice. PKH-labeled cells homed to the femur within minutes after injection into a peripheral vein. Most cells drifted within the marrow space and gradually seeded in clusters close to the endosteal surface of the epiphyseal cortex. Three days after transplantation 85% to 94% (14%) of PKH-labeled cells in the femoral marrow were located within 100 microm of the epiphyseal bone surface (P <.001 versus the more central cells), whereas labeled cells were absent in the femoral diaphysis. Primary seeding of juxtaendosteal, epiphyseal marrow occurred independently of recipient conditioning (myeloablated and nonconditioned hosts), donor-recipient antigen disparity, or the phenotype of the injected cells (whole BM and lineage-negative cells) and was consistently observed in secondary recipients of BM-homed cells. Seeding in regions close to the epiphyseal bone was also observed in freshly excised femurs perfused ex vivo and in femurs assessed without prior placement of optical windows, indicating that the site of primary seeding was not affected by surgical placement of optical windows. Four to 5 days after transplantation, cellular clusters appeared in the more central regions of the epiphyses and in the diaphyses. Centrally located cells showed decreased PKH fluorescence, suggesting that they were progeny of the seeding cells, and brightly fluorescent cells (quiescent first-generation seeding cells) were observed close to the bone surface for as long as 24 days after transplantation. These data indicate that the periphery of the femoral marrow hosts primary seeding and that quiescent cells continue to reside in the periphery for weeks and do not divide. The site of proliferation of transplanted cells is the center of the marrow space.

Tolerance induction in clinical transplantation: the pending questions

Despite the dramatic improvement of early graft survival due to the introduction of cyclosporin, late graft loss caused by chronic rejection and the lethal consequences of long-term immunosuppression, such as infection and cancer, remain major concerns for the transplantation community. Tolerance induction would avoid these complications. The ways to go are controversial, reflecting the redundancy of rejection pathways. They include the induction of central tolerance by establishment of mixed chimerism through hematopoietic stem cell transplantation and the induction of "operational tolerance" through immunodeviation involving dendritic or regulatory T cells. Major advances have been made in animal models exploring these strategies and, some preliminary data are even now available in humans, allowing the initiation of pilot clinical trials. In this article, we discuss the key questions that these trials will have to address.

Optical imaging of PKH-labeled hematopoietic cells in recipient bone marrow in vivo

This work describes an optical technique for characterization of the early stages of hematopoietic stem cell (HSC) engraftment under physiological conditions and in real time. Bone marrow cells (BMCs) labeled with PKH membrane linkers were injected into conditioned recipients (B10-->B10.BR mice) preoperated for placement of optical windows over femoral epiphyses. Labeled cells were tracked in vivo by fluorescence microscopy. Cellular adhesion to the BM stroma was tested with laser tweezers, and viability was assayed by the propidium iodide (PI) exclusion test, as determined from energy-transfer measurements of the pair PKH67-PI in freshly excised femurs in situ. At optimal concentrations for in vivo tracking, 1-4 micro M PKH dyes neither impaired the viability of BMCs nor the capacity of allogeneic HSCs to reconstitute hematopoiesis in myeloablated recipients. The optical window allowed in vivo visualization of 23%-26% of the PKH-labeled BMCs in the femur. The homing efficiencies at 16 hours posttransplantation were quantified as 1.77% +/- 0.15% and 0.21% +/- 0.02% for syngeneic and allogeneic BMCs, respectively. In femurs excised 16 hours after transplantation, 70% +/- 9% of the cells were adherent to the BM stroma, and two-thirds of the cells were PI negative (viable). In vivo tracking and in situ assessment of labeled HSCs in recipient BM provide important quantitative and qualitative insights into the early stages of engraftment. Correlation of early events and the efficiency of durable engraftment serve as the basis for a systematic approach toward optimization of the conditions for transplantation.

Transplanted hematopoietic cells seed in clusters in recipient bone marrow in vivo

The process of hematopoietic stem and progenitor cell (HSPC) seeding in recipient bone marrow (BM) early after transplantation is not fully characterized. In vivo tracking of HSPCs, labeled with PKH dyes, through an optical window surgically implanted on the mouse femur revealed that transplanted cells cluster in the recipient BM. Within the first day after intravenous injection, 86 +/- 6% of the cells seeded in clusters (p < 0.001 versus scattered cells) in the endosteal surfaces of the epiphyses. The primary clusters were formed by concomitant seeding of 6-10 cells over an area of approximately 70 microm, and secondarily injected cells did not join the already existing clusters but formed new clusters. Major antigen-disparate HSPCs participated in formation of the primary clusters, and T lymphocytes were also incorporated. After 4 to 5 days, some cellular clusters were observed in the more central regions of the BM, where the brightness of PKH fluorescence decreased, indicating cellular division. These later clusters were classified as secondary, assuming that the mechanisms of migration in the BM might be different from those of primary seeding. Some clusters remained in the periphery of the BM and retained bright fluorescence, indicating cellular quiescence. The number of brightly fluorescent cells in the clusters decreased exponentially to two to three cells after 24 days (p < 0.001). The data suggest that the hematopoietic niche is a functional unit of the BM stromal microenvironment that hosts seeding of a number of transplanted cells, which form a cluster. This may be the site where auxiliary non-HSPC cells, such as T lymphocytes, act in support of HSPC engraftment.