Effector cells derived from host CD8 memory T cells mediate rapid resistance against minor histocompatibility antigen-mismatched allogeneic marrow grafts without participation of perforin, Fas ligand, and the simultaneous inhibition of 3 tumor necrosis factor family effector pathways.

Reduced-intensity conditioning regimens for transplant recipients have heightened awareness of immunologic resistance to allogeneic bone marrow transplants (BMT). Although T cell-mediated cytotoxicity has been assumed to play a role in the resistance against donor allogeneic hematopoietic stem and progenitor cell grafts, several studies have reported relatively unimpaired resistance by recipients who lack perforin, Fas ligand (FasL), and other cytotoxic mediators. This study compared the early kinetics of T cell-mediated resistance in B6 (H2b) cytotoxically normal versus deficient recipients after transplantation with major histocompatibility complex-matched, minor histocompatibility antigen (MiHA)-mismatched allogeneic marrow grafts. Wild-type B6 or cytotoxic double-deficient perforin-/-/gld+/+ (B6-cdd) mice were sensitized against major histocompatibility complex-matched BALB.B or C3H.SW (H2b) MiHA and transplanted with a high dose (1 x 10(7)) of T cell-depleted bone marrow. CD8 T memory cells were shown to be present in recipients before BMT, and anti-CD8 monoclonal antibody infusion abolished resistance, thus demonstrating that CD8 T cells are the host effector population. Donor-committed and high proliferative potential progenitor numbers were markedly diminished by 48 hours after transplantation in both wild-type B6 and B6-cdd anti-donor MiHA-sensitized recipients. These observations indicate that the resistance pathway used in the cytotoxic deficient mice was both potent and rapidly induced--consistent with a CD8 memory T-cell response. To examine the role of Tumor necrosis factor-like weak inducer of apoptosis (TWEAK)- and TL1A-mediated cytotoxicity in this strong resistance, newly generated monoclonal antibodies specific for these ligands were administered to B6-cdd recipients sensitized to donor antigens. Recipients of syngeneic B6-gfp bone marrow exhibited significant donor colony-forming unit numbers after BMT. In contrast, low or absent colony-forming unit levels were detected in allogeneic recipients, including those that lacked perforin and FasL and that received anti-TWEAK, anti-tumor necrosis factor-related apoptosis-inducing ligand, and anti-TL1A monoclonal antibodies. These findings extend previous observations by demonstrating the existence of a rapidly effected resistance pathway mediated by memory CD8 effector T cells independent of the 2 major pathways of cytotoxicity. Together with previous findings, these results support the notion that effector cells derived from memory CD8 T-cell populations can mediate strong resistance against donor allogeneic MiHA-disparate hematopoietic engraftment by using a mechanism that is independent of the contribution of perforin, FasL, and the known death ligand receptor pathways.     

Photochemical treatment of donor lymphocytes inhibited their ability to facilitate donor engraftment or increase donor chimerism after nonmyeloablative conditioning or establishment of mixed chimerism.

Donor T-cells can provide a graft-versus-leukemia effect and help to promote donor engraftment after allogeneic BMT; however, these benefits can be outweighed by the ability of the cells to induce life-threatening GVHD. Photochemical treatment (PCT) of T-cells with S-59 psoralen and long-wavelength UV-A light can inhibit their proliferative capacity and significantly decrease their ability to induce acute GVHD after allogeneic BMT. PCT donor T-cells have been shown to facilitate donor engraftment in a myeloablative BMT model. In this study, we examined whether donor T-cells subjected to PCT ex vivo could retain the ability to facilitate engraftment or increase donor chimerism after nonmyeloablative BMT or after establishment of mixed hematopoietic chimerism. In a transplantation model in which mice were conditioned for BMT with sublethal (600 cGy) TBI, an infusion of PCT donor T-cells was unable to facilitate engraftment of donor BM. A BMT model was used in which a mixture of allogeneic and syngeneic marrow cells was infused into lethally irradiated recipients for establishment of mixed hematopoietic chimerism. The goal was to determine whether PCT donor splenocytes could increase levels of donor chimerism. Recipients of splenocytes treated with UV-A light only (no S-59 psoralen) and given at the time of BMT or in a donor lymphocyte infusion (DLI) had significantly higher levels of donor chimerism than did recipients of BM only. Although PCT donor splenocytes given at the time of BMT modestly increased donor chimerism, PCT donor splenocytes given in a DLI did not increase donor chimerism. A nonmyeloablative BMT model was employed for determining whether DLI given relatively late after BMT could increase donor chimerism. Recipient mice were conditioned for BMT with a combination of low-dose TBI (50 or 100 cGy) and anti-CD154 (anti-CD40L) monoclonal antibody for achievement of low levels of mixed chimerism. When control mixed chimeras were given a DLI 71 days after BMT, donor chimerism was significantly increased. In contrast, PCT of the donor cells eliminated the ability of the cells to increase donor chimerism after infusion. Together results from these 3 distinct BMT models indicate that PCT of donor T-cells significantly inhibited the ability of the cells to facilitate donor engraftment after nonmyeloablative BMT or to increase donor chimerism in mixed hematopoietic chimeras when the cells were administered in a DLI.     

Multiple mixed chimeras: reconstitution of lethally irradiated mice with syngeneic plus allogeneic bone marrow from multiple strains

Reconstitution of lethally irradiated B10 mice with a mixture of 5 x 10(6) B10 plus 15 x 10(6) B10.D2 T-cell-depleted (TCD) bone marrow (BM) cells has previously been shown to produce stable, mixed chimeras which are specifically tolerant to donor skin grafts; the inclusion of TCD syngeneic marrow in the inoculum leads to improved immunocompetence in the resulting chimeras. In order to determine whether this method of transplant tolerance induction could be extended to multiple simultaneous allogeneic donors, we have investigated the engraftment capacity of combinations containing syngeneic and more than one allogeneic source of bone marrow. B10 mice were lethally irradiated and reconstituted with a mixture of (B10 + B10.D2 + B10.BR) or (B10 + B10.RIII + B10.BR) TCD BM. Analysis of each group of animals by flow microfluorometry provided evidence for stable multiple mixed chimerism in the majority of animals. All animals which exhibited such multiple chimerism were also tolerant of skin grafts from both allogeneic donors and promptly rejected fourth party skin grafts. An attempt to produce chimerism with TCD marrow from 5 allogeneic plus syngeneic BM cells was less successful. When animals were given non-TCD allogeneic BM from 2 allogeneic donors along with TCD syngeneic BM, they reconstituted as fully allogeneic chimeras in which one or the other allogeneic donor prevailed. These results indicate that (1) multiple allogeneic donor BM cells can engraft simultaneously in the mixed marrow model, but there may be a limit to the number of marrow strains which can repopulate a single animal; (2) multiple allogeneic engraftment confers transplantation tolerance to multiple donors; and (3) TCD is essential to permit multiple mixed chimerism to develop.     

Lack of correlation between an assay used to determine early marrow allograft rejection and long-term chimerism after murine allogeneic bone marrow transplantation: effects of marrow dose.

The acute rejection of bone marrow (BM) allografts by host effectors can occur within a short period after BM transplantation (BMT) in lethally irradiated mice. Common assays used to ascertain engraftment/resistance involve measuring the growth of granulocyte/monocyte progenitors (colony-forming unit-granulocyte-macrophage) in vitro or splenocyte proliferation assessed by radioisotope incorporation in vivo 5 to 8 days after BMT. However, the correlation of the long-term outcome of BMT with the kinetics of recovery by using the dose of allogeneic BM cells (BMCs) that leads to early rejection as determined by the in vitro assessment has not been extensively studied. Thus, to investigate whether the early rejection of donor BMCs is an indication of a long-term engraftment failure, C57BL/6 (H2b) mice were lethally irradiated and transplanted with various doses of BALB/c (H2d) BMCs. The short-term engraftment of donor precursors (colony-forming unit-granulocyte-macrophage), the kinetics of hematopoietic cell recovery, the extent of donor chimerism, and the proportion of the recipients with long-term survival were determined. The results show that the kinetics and extent of hematopoietic cell recovery were significantly delayed in mice receiving limiting doses of BMCs that were rejected or severely resisted at day 8 after BMT. However, a proportion of these mice survived up to 98 days after BMT with mixed chimerism or donor chimerism. This study demonstrates that early rejection of BM precursors, as assessed by measurement of myeloid progenitors in the spleen after BMT, does not always correlate with the long-term outcome of the marrow allograft and that significant variability is inherent in the extent of chimerism when threshold amounts of BMCs are used.     

CD25+ immunoregulatory T-cells of donor origin suppress alloreactivity after BMT.

We have previously identified donor-derived Thy1+ alphabeta T-cell receptor (TCR)+ CD4+ CD8- regulatory T-cells that suppress GVH reactivity induced by donor leukocyte infusion (DLI) after BMT. These cells develop in the recipient thymus and may play a role in the maintenance of donor-host tolerance after allogeneic BMT. In the present study, we sought to further characterize the T-cells responsible for the regulatory cell activity in our model. Lethally irradiated recipient AKR mice (H-2k) received transplants of BM from CD25-deficient (-/-) C57BL/6 mice (H-2b). Recipients of CD25-deficient BM developed more severe GVHD after DLI than did recipients of normal BM, a result that indirectly suggests that CD4+ CD25+ regulatory T-cells are important to the suppression of GVH reactivity after allogeneic BMT. GVHD was accompanied by mortality, body weight loss, and elevated percentages of T-cells from the DLI in the peripheral blood in mice that received CD25-deficient BM compared to mice that received normal BM. Both CD40-CD40L and CD28-B7 costimulatory pathways have been implicated in the generation of CD25+ regulatory T-cells. Therefore, we tested whether deficiency in either of these pathways affected the activity of donor BM-derived regulatory T-cells. The absence of CD40L did not affect the regulatory T-cells (ie, recipient mice were still protected from DLI-induced GVHD). In contrast, use of marrow from CD28-deficient mice resulted in complete loss of suppression of GVH reactivity. Thus, CD28 but not CD40L was critical for the generation and/or activation of immunoregulatory T-cells that suppressed GVHD induced by DLI. Together, the results of these experiments suggest that CD4+ CD25+ regulatory T-cells suppress GVH reactivity after BMT and that CD28 expression is indispensable for the generation of these cells.     

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.     

Transplantation of X-linked severe combined immunodeficient dogs with CD34+ bone marrow cells.

X-linked severe combined immunodeficiency (X-SCID) is the most common form of human SCID and is caused by mutations in the common gamma chain (gammac), a shared component of the interleukin (IL)-2, IL-4, IL-7, IL-9, IL-15, and IL-21 receptors. BMT for human X-SCID results in engraftment of donor T-cells and reconstitution of normal T-cell function but engraftment of few, if any, donor B-cells and poor reconstitution of humoral immune function. Canine X-SCID is also caused by mutations in the yc and has an immunological phenotype identical to that of human X-SCID. We have previously reported that transplantation of nonconditioned X-SCID dogs with unfractionated histocompatible bone marrow results in engraftment of both donor B- and T-cells and reconstitution of normal T-cell and humoral immune function. In this study, we assessed the ability of purified canine CD34+ bone marrow cells to reconstitute lymphoid populations after histocompatible BMT in 6 nonablated X-SCID dogs. All dogs showed engraftment of donor T-cells, with T-cell regeneration occurring through a thymic-dependent pathway, and had reconstituted normal T-cell function. In contrast to our previous studies, only 3 dogs had engraftment of donor B-cells and reconstituted normal antigen-specific B-cell function post-BMT. The variable donor B-cell engraftment and reconstitution of normal humoral immune function observed in this study are similar to the outcomes observed in the majority of human X-SCID patients following BMT. This study demonstrates that canine CD34+ cells contain progenitors capable of immune reconstitution and is the first study to document the ability of CD34+ bone marrow cells to reconstitute normal B- and T-cell function in a nonablated large-animal model of BMT. This study also demonstrates that the quality of immune reconstitution following CD34+ BMT may be dosage dependent Thus canine X-SCID provides a large-animal preclinical model that can be used not only to determine the optimal conditions for both donor B- and T-cell engraftment following CD34 BMT, but also to develop and evaluate strategies for gene therapy protocols that target CD34 cells.     

Induction of mixed chimerism through transplantation of CD45-congenic mobilized peripheral blood stem cells after nonmyeloablative irradiation.

Clinical translation of the mixed-chimerism approach for inducing transplantation tolerance would be facilitated if mobilized peripheral blood stem cells (mPBSCs) could be used instead of bone marrow cells (BMCs). Because the use of mPBSCs for this purpose has not been investigated in nonmyeloablative murine protocols, we explored the engraftment potential of mPBSCs in a CD45-congenic model as a first step. After 2, 1.5, or 1 Gy of total body irradiation, CD45.1 B6 hosts received unseparated granulocyte colony-stimulating factor-mobilized CD45.2 B6 PBSCs or unseparated CD45.2 B6 BMCs. The same total cell numbers, or aliquots of mPBSCs and BMCs containing similar numbers of c-kit+ cells, were transplanted both with and without a short course of rapamycin-based immunosuppression (IS). Transplantation of mPBSCs induced long-term multilineage macrochimerism, but chimerism levels were significantly lower than among recipients of the same number of BMCs. Transplanting aliquots containing similar numbers of c-kit+ cells reduced the difference between mPBSCs and BMCs, but lower levels of chimerism were nonetheless observed in mPBSC recipients. Chimerism levels correlated more closely with the number of transplanted progenitor cells as determined by colony-forming unit assays. IS did not affect chimerism levels, indicating that the donor CD45 isoform or other minor disparities do not pose a major barrier to engraftment. Our findings indicate that under nonmyeloablative conditions, progenitor cells contained in mPBSCs have an engraftment capacity similar to progenitor cells from BMCs, allowing induction of lasting mixed chimerism with moderate cell numbers. On a cell-per-cell basis, unseparated BMCs have some advantages that may be minimized if the number of progenitor cells is equalized. These results are expected to facilitate the development of mPBSC-based allogeneic tolerance protocols.     

B7.2-/- mature dendritic cells generate T-helper 2 and regulatory T donor cells in fetal mice after in utero allogeneic bone marrow transplantation.

In utero hematopoietic stem cell transplantation (IUT) results in limited chimerism and tolerance to alloantigens. We studied the relative role of B7.1 and B7.2 expression by dendritic cells (DCs) in engraftment and in generating donor-specific tolerance in fetal mice. Mature dendritic cells (mDCs) from B7.1(-/-) or B7.2(-/-) donors and wild-type (WT) lineage-depleted (lin(-)) C57BL/6 (B6) bone marrow (BM) were injected into BALB/c fetuses. Six weeks after IUT, B7.1(-/-) recipients had multilineage engraftment (4.7% +/- 0.8% T cells and 5.7% +/- 1.1% granulocytes) associated with graft-versus-host disease (GVHD) and decreased survival, but by 12 weeks only donor CD3(+) cells (2.1% +/- 1.3%) were present. Recipients of B7.2(-/-) mDCs and lin(-) WT B6 BM had exclusively CD3(+)CD4(+) T cells (11.8% +/- 8.5% at 6 weeks and 6.5% +/- 2.5% at 12 weeks). Most of the cells were T-helper 2, although 10.4% +/- 1.4% were of the T-regulatory (T(reg)) phenotype, ie, CD4(+)CD25(+). Donor T(reg) cells were detected both in the thymus and spleen, thus suggesting an effect on both central and peripheral immunity. The animals with T(reg) cells had better survival (82.3% versus 47.4%; P < .01) and no GVHD (0% versus 65%; P < .001). This group alone demonstrated multilineage engraftment of donor hematopoietic cells after postnatal transplantation with megadoses of donor lin(-) BM. Both the engrafted donor CD4(+)CD25(-) and CD4(+)CD25(+) cells induced comparable in vitro suppression of T-cell proliferation, thus suggesting their role in the persistence of the donor T cells in vivo. The CD4(+)CD25(-) cells produced interleukin 10 or interleukin 4 and were inhibited by anti-T-helper 2 cytokine-neutralizing antibodies, whereas the CD4(+)CD25(+) cells showed no evidence of any involvement of a cytokine-like soluble mediator and expressed cytotoxic T-lymphocyte antigen 4 (CTLA-4) and foxp3 constitutively. Donor mDCs and donor CD4 T cells were detected among the thymocytes of the recipients of B7.2(-/-) mDCs and lin(-) WT B6 BM. Thus, it seems that costimulatory molecule expression of donor DCs can play a significant immunomodulatory role in survival, GVHD, engraftment, and homing of allogeneic BM cells after IUT through the generation of T(reg) cells.     

Assessment of lineage-specific chimerism after allogeneic stem cell transplantation

IntroductionDonor lineage-specific chimerism of hematopoietic cells enables very precise monitoring of engraftment in selected cell lines after allogeneic stem cell transplantation (allo-SCT).Materials and methodsThe study group consisted of 12 acute leukemia patients who underwent allo-SCT in the Department of Hematology and Bone Marrow Transplantation in Katowice, Poland. Lineage-specific chimerism was assessed in B cells (CD19+ CD38−/+), plasma cells (CD19+ CD38++), T cells (CD3+ or CD7+ CD56−), monocytes (CD14+), and immature progenitor cells deriving from myeloid line (CD34+CD19). We also assessed erythrocyte chimerism by flow cytometry.ResultsAll patients engrafted. 8 out of 10 patients presented normal donor hematopoiesis. Lineage specific chimerism in these patients corresponded with chimerism analysis in unsorted material and with undetectable minimal residual disease (MRD). Relapse of the underlying disease was diagnosed in 2 patients. In both cases loss of donor chimerism occurred in leukemia specific cell line and corresponded with detectable MRD. One patient with secondary graft failure presented decreasing lineage specific chimerism in all subpopulations, with negative MRD status. In 10 patients normal hematopoiesis of donor-origin was assessed by flow cytometry. In one case no donor-derived erythrocytes were detected and the diagnosis of pure red cell aplasia was set.ConclusionsLineage specific chimerism as a method of high sensitivity and specificity allows for precise assessment of donor chimerism especially in clinically ambiguous situations. Assessment of erythrocyte chimerism by flow cytometry is a reliable method of monitoring erythroblastic line engraftment. Presented results are preliminary and the study is being continued.     

CD8hi+CD57+ T lymphocytes are enriched in antigen-specific T cells capable of down-modulating cytotoxic activity

Major expansions of CD8hi+CD57+ T lymphocytes frequently occur during human immunodeficiency virus (HIV) infection and after transplantation. To investigate mechanisms of such cell expansion, we compared the activation and functional status of CD8hi+CD57+ and CD57-peripheral blood lymphocytes (PBL) from normal, bone marrow transplantation (BMT) and HIV+ donors. The CD8hi+CD57+ PBL from BMT and HIV+ donors preferentially displayed CD38 and HLA-DR activation markers without correlation between CD8hi+CD57+ percentages and HIV load, the CD45RA+ isoform in all ex vivo conditions but acquired CD45RO after in vitro expansion, CD11b and CD11c in BMT and HIV+ donors but decreased expression of CD62-L, VLA-2 and VLA-6. The CD8hi+CD57+ cells were positive for perforin and granzyme B and spontaneously mediated cytolytic activity in a CD3-redirected assay. In contrast the inhibitor of cytolytic functions (ICF) produced by CD8hi+CD57+ cells down- modulated the CD3-redirected cytolytic activity but only at low levels of CD3 cross-linking. While CD3-triggering induced a low, if any, short- term proliferation of CD8+CD57+ cells, this subset could be amplified after long-term stimulation either with mitogens or with HIV antigens, thereby enriched in HIV-specific T cells producing tumor necrosis factor-alpha. Altogether these data suggest that CD8hi+CD57+ cells represent a terminal differentiation state of activated effector cytotoxic T lymphocytes which are enriched in antigen-specific T cells and down-modulate their own cytolytic potential, thus participating in a negative control of effector cell functions during persistent viral infections or transplantations.      

Donor double-negative Treg promote allogeneic mixed chimerism and tolerance

Bone marrow (BM) transplantation is an efficient approach to develop donor-specific tolerance and prevent chronic rejection. Allogeneic BM transplantation is limited by donor T cell-mediated graft-versus-host disease, requirement of cytoreduction and high numbers of BM cells. In addition of these drawbacks, recent studies demonstrate that not only T cells, but also NK cells can mediate BM rejection, and long-term mixed chimerism depends on NK cell tolerance. Thus, NK cell is another potential barrier against engraftment of BM and an important target in efforts to induce transplant tolerance. We have previously identified a novel type of Treg with the phenotype TCRalphabeta+CD3+CD4-CD8- (double-negative, DN). We and others have demonstrated that DN-Treg can effectively suppress anti-donor T cell responses. In this study, we found that donor-derived DN-Treg can suppress NK cell-mediated allogeneic BM graft rejection in both parent-to-F1 and fully MHC-mismatched BM transplantation models. Perforin and FasL in DN-Treg play important roles in the suppression of NK cells. Furthermore, adoptive transfer of DN-Treg can promote a stable mixed chimerism and donor-specific tolerance without inducing graft-versus-host disease. These results demonstrate a potential approach to control innate immune responses and promote allogeneic BM engraftment.     

In utero hematopoietic stem cell transplantation in nonhuman primates: the role of T cells

In utero transplantation of hematopoietic stem cells is a promising treatment for immune and hematologic diseases of fetuses and newborns. Unfortunately, there are limited data from nonhuman primates and humans describing optimal transplantation conditions. The purpose of this investigation was to determine the effect of T-cell number on engraftment and the level of chimerism after in utero transplantation in nonhuman primates. CD34(+) allogeneic adult bone marrow cells, obtained from the sire after G-CSF and stem cell factor administration, were transplanted into female fetal recipients. The average CD34(+) cell dose was 3.0 x 10(9)/kg (range, 9.9 x 10(8) to 4.4 x 10(9)) and the T-cell dose ranged from 2.6 x 10(5) to 1.1 x 10(8)/kg. Chimerism was determined in peripheral blood subsets (CD2, CD13, and CD20) and in progenitor cell populations by using polymerase chain reaction. Chimerism was noted in seven of eight live-born animals. The level of chimerism in the progenitor population was related to the fetal T-cell dose (r = 0.64, p < 0.02). At the lowest T-cell dose (2.6 x 10(5)/kg), no chimerism was detected. As the T-cell dose increased to 10(6-7)/kg, the level of chimerism increased. Adjusting the T-cell dose to 1.1 x 10(8)/kg resulted in fatal graft-versus-host disease (GVHD). The results of this study emphasize the importance of T cells in facilitating donor cell engraftment and in producing GVHD in fetal nonhuman primates. Some animals achieved levels of chimerism in the marrow hematopoietic progenitor cell population that would likely have clinical relevance. However, the levels of chimerism in peripheral blood were too low for therapeutic benefit. Further studies are needed to test methods that are likely to enhance donor cell engraftment and peripheral blood levels of donor cells.     

Pilot study of allogeneic G-CSF-stimulated bone marrow transplantation: harvest, engraftment, and graft-versus-host disease.

Peripheral blood progenitor cell (PBPC) harvests mobilized by granulocyte colony-stimulating factor (G-CSF) contain more CD34+ cells and provide more rapid engraftment than do bone marrow (BM) harvests. However, some reports have suggested a higher risk of chronic graft-versus-host disease (GVHD), possibly because such PBPC harvests contain approximately 10 times more T lymphocytes than do BM harvests. Some groups are attempting to combine the faster engraftment of PBPCs with the lower incidence of GVHD observed after BM transplantation by using G-CSF-primed BM conventionally harvested from iliac crests for allogenic BM transplantation. We report the results of a pilot study of 38 allogeneic transplants using G-CSF-stimulated BM from related donors, with a focus on the harvest composition, engraftment, and incidence of acute and chronic GVHDs.     

Deletional and regulatory mechanisms coalesce to drive transplantation tolerance through mixed chimerism

Establishing donor‐specific immunological tolerance could improve long‐term outcome by obviating the need for immunosuppressive drug therapy, which is currently required to control alloreactivity after organ transplantation. Mixed chimerism is defined as the engraftment of donor hematopoietic stem cells in the recipient, leading to viable coexistence of both donor and recipient leukocytes. In numerous experimental models, cotransplantation of donor bone marrow (BM) into preconditioned (e.g., through irradiation or cytotoxic drugs) recipients leads to transplantation tolerance through (mixed) chimerism. Mixed chimerism offers immunological advantages for clinical translation; pilot trials have established proof of concept by deliberately inducing tolerance in humans. Widespread clinical application is prevented, however, by the harsh preconditioning currently necessary for permitting BM engraftment. Recently, the immunological mechanisms inducing and maintaining tolerance in experimental mixed chimerism have been defined, revealing a more prominent role for regulation than historically assumed. The evidence from murine models suggests that both deletional and regulatory mechanisms are critical in promoting complete tolerance, encompassing also the minor histocompatibility antigens. Here, we review the current understanding of tolerance through mixed chimerism and provide an outlook on how to realize widespread clinical translation based on mechanistic insights gained from chimerism protocols, including cell therapy with polyclonal regulatory T cells.     

Immunogenicity of Ly5 (CD45)-antigens hampers long-term engraftment following minimal conditioning in a murine bone marrow transplantation model

Various techniques are available for distinguishing donor from host cells evaluating the efficacy of conditioning regimen for experimental bone marrow transplantation (BMT). Techniques include the use of extracellular immunological markers, such as Ly5 (CD45), and intracellular biochemical markers, such as glucose-phosphate-isomerase (Gpi). Because Ly5 is an extracellular protein, the disparity between donor (Ly5.1) and host (Ly5.2) antigens may induce a weak immune response whereas with Gpi, no immune response is expected. This difference may be of particular concern in experimental transplantation approaches that use minimal conditioning such as low-dose total body irradiation (TBI). Such mild conditioning may not induce the immunosuppression required to overcome host rejection of Ly5 disparate cells. To compare the relative engraftment of Ly5.1 and Gpi-1(a) donor marrow, B6 (Gpi-1(b)/Ly5.2) mice were irradiated with low-level TBI (0-6 Gy) and transplanted with several bone marrow (BM) doses (2 x 10(6)-5 x 10(7) cells). At 8, 26, and 52 weeks post-BMT, the level of donor engraftment was measured using flow cytometry (Ly5) or Gpi-electrophoresis. Lower engraftment levels were found in mice transplanted with Ly5 congenic BM in groups given low-dose TBI (< or = 4 Gy) and/or low doses of BM cells (BMC) (2 x 10(6)). However, when higher TBI or BMC doses were used, similar engraftment levels were found, suggesting sufficient immune suppression to allow equal engraftment of both sources of BM. These data suggest that even a minor phenotypic disparity between donor and host, such as Ly5, may necessitate high-dose TBI to prevent rejection. The combination of low-dose TBI or other nonmyeloablative conditioning strategies with small numbers of BMC may lead to reduced engraftment when extracellular immunological markers such as Ly5 are used for transplantation studies. Therefore, small immunological differences must be considered when using the Ly5 marker for engraftment.     

Mouse models of hematopoietic engraftment: limitations of transgenic green fluorescent protein strains and a high-performance liquid chromatography approach to analysis of erythroid chimerism

Transgenic mouse strains ubiquitously expressing green fluorescent protein (GFP) have enabled investigators to develop in vivo transplant models that can detect donor contributions to many different tissues. However, most GFP transgenics lack expression of the reporter in the erythroid lineage. We evaluated expression of GFP in the bone marrow of the OsbY01 transgenic mouse (B6-GFP) in the context of CD71 and TER-119 expression and found that GFP fluorescence is lost prior to the basophilic erythroblast stage of development. However, platelets in B6-GFP mice were found to be uniformly positive for GFP. We therefore used the GFP transgenic model in combination with allelic variants of CD45 and the hemoglobin beta (Hbb) chain to develop a model system that allows all blood lineages to be followed in a mouse model of bone marrow transplantation (BMT). To detect Hbb variant molecules, we developed a new protocol based on high-performance liquid chromatography that is sensitive and precise, allowing rapid and quantitative analysis of erythroid chimerism. Platelet and leukocyte engraftment were detected by flow cytometry. BMT into sublethally irradiated (4 Gy) recipients demonstrated the failure of B6-GFP-derived cells to engraft relative to B6-CD45(a)-derived cells, suggesting that an immune barrier may prevent efficient engraftment of the transgenic cells in a setting of minimal ablation. These results establish limitations in the use of transgenic GFP expression as a donor marker in transplantation models.     

Host T cells affect donor T cell engraftment and graft-versus-host disease after reduced-intensity hematopoietic stem cell transplantation.

Mixed chimerism in the T cell compartment (MCT) after reduced-intensity stem cell transplantation (RIST) may influence immune repopulation with alloreactive donor T cells. We examined effects of host T cell numbers on donor T cell engraftment and recovery and on acute graft-versus-host disease (aGVHD) in a relatively homogeneous patient population with respect to residual host T cells through quantified immune depletion prior to RIST and to donor T cells by setting the allograft T cell dose of 1x10(5) CD3+ cells/kg. In this setting, 2 patterns of early donor T cell engraftment could be distinguished by day +42: (1) early and complete donor chimerism in the T cell compartment (FDCT) and (2) persistent MCT. FDCT was associated with lower residual host CD8+ T cell counts prior to transplant and aGVHD. With persistent MCT, subsequent development of aGVHD could be predicted by the direction of change in T cell donor chimerism after donor lymphocyte infusion, and no aGVHD occurred until FDCT was established. MCT did not affect recovery of donor T cell counts. These observations suggest that the relative number and alloreactivity of donor and host T cells are more important than the absolute allograft T cell dose in determining donor engraftment and aGVHD after RIST.     

The effect of the spleen on compartmental levels and distribution of donor progenitor cells after syngeneic and allogeneic bone marrow transplants

These studies investigate the involvement of the spleen in progenitor (PC) cell numbers and "cross-talk" with the marrow compartment following syngeneic or allogeneic bone marrow transplantation (BMT) in sham or fully splenectomized mice. Intact recipient B6 mice were lethally irradiated prior to transplant with T cell-depleted bone marrow (BM-TCD). The kinetics of PC reconstitution following i.v. transplant consistently revealed a dramatic increase in splenic colony-forming unit interleukin-3 (CFU IL-3) and CFU (high proliferative potential-(HPP) levels between days 5 and 12 post-BMT. Direct injection of TCD-BM into the recipient marrow cavity did not alter this pattern of reconstitution in the splenic compartment. In contrast to spleens from normal adult B6 mice containing 0.9% and 0.6% of the total combined splenic and marrow committed (CFU IL-3) and primitive (CFU-HPP) progenitors, respectively, spleens of syngeneic BMT recipients at day 12 contained a 10-fold increase (p < 0.001) over the progenitor levels in normal spleens. These splenic numbers decreased to normal, homeostatic levels by day 28 post-BMT. In contrast, the level of marrow CFU IL-3 progenitors continued to increase post-transplant, reaching near homeostatic levels by day 28 post-BMT. Interestingly, early seeding of 5- (and -6)carboxyfluorescein diacetate succinimidyl ester (CFSE)-labeled or green fluorescent protein (GFP) donor bone marrow cells (BMC) to the marrow compartment was not different in sham splenectomies or recipients splenectomized 14 days earlier. However, recipient splenectomy consistently resulted in significantly higher numbers of CFU IL-3 in the bone marrow during the first 2 weeks post-transplant compared to sham controls. These elevated levels exceeded the combined progenitor numbers of the splenic and marrow compartments of intact recipients. Notably, this increase in marrow progenitor activity in splenectomized recipients was observed after syngeneic as well as allogeneic BMT. Allogeneic transplants across major, or those limited to minor, histocompatibility antigen differences exhibited this increased marrow progenitor activity. Splenectomy performed 2 h post-transplant to assure "normal" marrow seeding also resulted in higher marrow progenitor activity. Thus, this "marrow response" to splenectomy is not induced by early "shunting" of infused BM cells to the marrow compartment. These results suggest that communication between the splenic and marrow compartments following syngeneic and allogeneic BMT exists during early hematopoietic reconstitution, one effect of which is to impact the compartmental distribution of donor progenitor cells. The role of the spleen on engraftment, chimerism, and tolerance in allogeneic BMT models are now under investigation.     

Fludarabine-based conditioning secures engraftment of second hematopoietic stem cell allografts (HSCT) in the treatment of initial graft failure.

Graft failure is associated with a high mortality rate. To date, regimens invoked for second transplants have resulted in inconsistent engraftment with high transplant-related mortality (TRM). We here report 16 consecutive patients, aged 4-59 years, who received second HSCT (HSCT-2) at a median of 45 days following primary or secondary failure of an initial unmodified (N = 3) or T cell-depleted (TCD) (N = 13) HSCT (HSCT-1). HSCT-1 was administered after myeloablative total body irradiation (TBI)- or alkylator-based conditioning for acute leukemias (N = 7), MDS (N = 6), CML (N = 2), and Fanconi anemia (N = 1). All patients experienced 1 or more infectious complications between HSCT-1 and HSCT-2, and 10 patients had active infections at the time of HSCT-2. Cytoreduction regimens used for HSCT-2 included fludarabine (Flu) in combination with cyclophosphamide (CTX) (N = 9), or thiotepa (Thio) (N = 5). In addition, 1 patient received Flu alone and 1 patient Thio combined with CTX. Antithymocyte globulin (ATG) (N = 11) or Alemtuzumab (N = 3) was added pretransplant to prevent rejection. For HSCT-2, donors included HLA-matched (N = 3) or mismatched (N = 8) related, or matched (N = 2) or mismatched (N = 3) unrelated donors. The primary graft donor was used in 6 of 16 cases. The grafts administered were unmodified peripheral blood stem cell transplantation (PBSCT) (N = 5) or bone marrow transplantation (BMT) (N = 3), TCD PBSCT (N = 8). All patients achieved engraftment at a median of 12 days and evaluable patients achieved complete donor chimerism. Six patients are alive with a median follow-up of 49 months, including 4/9 conditioned with Flu/CTX. In this series, outcome was statistically superior for younger patients (相似文献