Leukemia relapse in host cells 5 years after bone marrow transplantation for acute non-lymphocytic leukemia in first complete remission

A case of leukemia relapse in a 15-year-old girl occurring 5 years after successful allogeneic bone marrow transplantation for acute non-lymphocytic leukemia is reported. Laboratory findings demonstrated that this relapse was in host cells and had the same phenotype as the original leukemia. Incomplete lymphoid chimerism after bone marrow transplantation might have resulted in an inappropriate graft-versus-leukemia effect.     

Impact of pretransplant conditioning and donor T cells on chimerism, graft-versus-host disease, graft-versus-leukemia reactivity, and tolerance after bone marrow transplantation

Graft rejection, mixed chimerism, graft-versus-host disease (GVHD), leukemia relapse, and tolerance are interrelated manifestations of immunologic reactivity between donor and host cells that significantly affect survival after allogeneic bone marrow transplantation (BMT). In this report, a mouse model of BMT, in which the donor and host were compatible at the major histocompatibility complex (MHC), was used (1) to examine the interrelationship of pretransplant conditioning and T-cell content of donor BM with regard to lymphoid chimerism and GVHD and (2) to determine how these factors affected graft-versus-leukemia (GVL) reactivity and donor-host-tolerance. AKR (H-2k) host mice were administered optimal or suboptimal total body irradiation (TBI) as pretransplant conditioning followed by administration of BM cells from B10.BR (H-2k) donor mice with or without added spleen cells as a source of T lymphocytes. Transplanted mice were injected with a supralethal dose of AKR leukemia cells 20 and 45 days post-BMT to assess GVL reactivity in vivo. The pretransplant conditioning of the host and T-cell content of the donor marrow affected the extent of donor T-cell chimerism and the severity of GVH disease. GVL reactivity was dependent on transplantation of mature donor T cells and occurred only in complete chimeras. Transplantation of T-cell-deficient BM resulted in the persistence of host T cells, ie, incomplete donor T-cell chimerism, even when lethal TBI was used. Mixed chimerism was associated with a lack of GVL reactivity, despite the fact that similar numbers of donor T cells were present in the spleens of mixed and complete chimeras. In this model, moderate numbers of donor T cells facilitated complete donor T-cell engraftment, caused only mild GVHD, and provided a significant GVL effect without preventing the subsequent development of tolerance after conditioning with suboptimal TBI. In contrast, severe, often lethal, GVHD developed when the dose of TBI was increased, whereas tolerance and no GVH/GVL reactivity developed when the T-cell content of the marrow was decreased.     

Transplantation of HLA-haploidentical T-cell-depleted marrow for leukemia: autologous marrow recovery with specific immune sensitization to donor antigens

Autologous marrow recovery without engraftment of donor marrow was observed after bone marrow transplantation (BMT) for two patients with acute lymphoblastic leukemia. Each had received marrow from a haploidentical mixed lymphocyte culture (MLC) reactive donor after pretransplant conditioning with total body irradiation and high-dose cyclophosphamide. To minimize graft-vs-host disease, the marrow was depleted of T cells in vitro by treatment with a monoclonal anti-T-cell antibody and complement. Two weeks after each transplant, reactive lymphocytes were noted transiently in the blood of each patient. Analysis of karyotype, HLA type, and in vitro MLC responsiveness proved the lymphocytes to be of host, not donor, origin. MLC studies showed rapid proliferative responses specifically to stimulating cells from the BMT donor, indicating in vivo sensitization to donor antigens. Return of hematopoietic function was markedly delayed, but it eventually normalized after several months, without evidence of chimerism. These studies confirm that some immune and hematopoietic stem cells of host origin survive the high-dose chemoradiotherapy used as transplant conditioning. Because these immune cells are specifically reactive to donor alloantigens, more potent suppression of host immunity may be needed to prevent nonengraftment of T-cell-depleted, HLA-mismatched bone marrow.     

Mixed chimerism after bone marrow transplantation for thalassemia major

Thirty-four thalassemia patients were studied for chimerism by fluorescent in situ hybridization or variable number tandem repeats after bone marrow transplantation. Mixed chimerism was detected in 9 patients with host cells ranging from 4 to 56%. One had graft rejection and the others were transfusion independent. Mixed chimerism was common but mostly without deleterious effect.     

Therapy-related leukemia and myelodysplasia in small-cell lung cancer. Report of a case and results of morphologic, cytogenetic, and bone marrow culture studies in long-term survivors

The bone marrow of 11 patients with small-cell lung cancer, who survived more than two years following combined-modality therapy, was subjected to morphologic, cytogenetic, and bone marrow culture studies. One patient, after a prodrome of anemia and thrombocytopenia, developed acute leukemia 60 months after the start of chemotherapy. Four months before frank leukemia developed, bone marrow culture studies showed a marked inability to form colonies. Cytogenetic studies demonstrated an abnormal clone of cells that included the deletion of the long arm of chromosome 5. No morphologic abnormalities were noted in the bone marrow of any other long-term survivor; however, the mean corpuscular volume of peripheral red blood cells was greater than normal in three of four patients who remain alive and disease free. In one of these patients marrow culture studies also failed to grow colonies. The other patients showed a decreased ability to form multilineage colonies and colonies of the granulocyte-macrophage lineage in vitro compared with a control population. All patients showed some degree of aneuploidy on cytogenetic analysis; in two cases approximately 50% of cells were aneuploid. However, no clonal abnormality was detected in any patient. Follow-up for the development of secondary acute leukemia and other long-term complications continues in these patients.     

Mixed hematopoietic chimerism following bone marrow transplantation for hematologic malignancies

Twenty-nine of 172 patients (17%) who received an allogeneic bone marrow transplant (BMT) from histocompatible sibling donors for hematologic malignancies were mixed hematopoietic chimeras; ie, they had a mixture of donor and host hematopoietic or lymphohematopoietic cells at greater than or equal to 14 days after transplantation. Twenty- four of the 29 mixed chimeras (83%) have remained in continuous complete remission for up to 116 months (greater than 9 years) following BMT. Four of the 29 patients (14%) have had recurrent leukemia, and 7 of the 29 (24%) have had moderate or severe graft-v- host disease (GVHD). Twelve of these 29 patients have persisted as stable mixed chimeras for greater than or equal to 2 years after BMT, whereas other patients converted to all donor-type hematopoiesis. The incidence of mixed chimerism was independent of the pretransplant regimen, the donor or recipient age (less than 20 v greater than 20 years), remission status (first complete remission of acute leukemia and first chronic phase of chronic myelocytic leukemia v later stages of disease), and type of leukemia. Our data indicate that mixed hematopoietic chimerism is not rare after BMT for hematologic malignancies and that its presence is compatible with long-term disease- free survival. Prospective studies of mixed chimerism after BMT are warranted to achieve better understanding of its biologic importance.     

Transplantation of chromosomally marked syngeneic marrow cells into mice not subjected to hematopoietic stem cell depletion

The percentage of donor-host chimerism was determined 4-6 weeks or six months after injection of normal bone marrow cells into normal syngeneic or coisogeneic recipient mice. Donor-recipient pairs had chromosome markers that provided easy identification of metaphase cells. The percentage of donor cells in marrow or spleen ranged from 0 to 16% and this percentage was independent of the age of recipient or attempts to stimulate hematopoiesis in donor and/or host mice. In adult C57BL/6 mice there was a roughly linear dose-response relationship between cell dose and percentage of chimerism. There was no apparent dose-response relationship for AKR mice. The percentage of donor cells in the spleen was correlated to that seen in the marrow of recipients. Neonatal mice given the same intraperitoneal marrow cell dose as weanlings, but a larger number of cells relative to their own marrow mass, did not show a larger percentage of chimerism than weanlings. Similarly, weanlings given the same intravenous dose as adults showed no greater degree of chimerism than adults. Temporary anemia, induced by bleeding donors prior to cell collection, or more chronic hemopoietic stimulus (produced by injecting recipients with phenylhydrazine prior to cell injection with subsequent bleeding at intervals) did not result in an increased percentage of chimerism. These results indicate that there are "empty" sites in bone marrow of normal mice in which injected hematopoietic stem cells can lodge and grow.     

Minimal residual disease is more common in patients who have mixed T- cell chimerism after bone marrow transplantation for chronic myelogenous leukemia

Determining both lymphoid chimerism and the presence of minimal residual disease after allogeneic bone marrow transplantation (BMT) for chronic myelogenous leukemia (CML) could be helpful to the understanding of the biology of leukemic relapse in this disease. We prospectively investigated 32 patients with CML post-BMT by assessing T- cell chimerism and minimal residual disease using sensitive polymerase chain reaction (PCR) methodologies. Patients were studied between 1 and 24 months post-BMT. Thirty patients received a T-cell-depleted marrow grafts and 2 received unmanipulated marrow. All but 1 patient were conditioned with total body irradiation (TBI)+thiotepa+cyclophosphamide (Cy). The other patient received TBI+Cy as conditioning. The T cells were exclusively of donor origin in 12 of 16 patients who were tested at 1 month post-BMT, but were mixed chimeric in 11 of these patients by > or = 3 months. Once mixed T-cell chimerism was documented, no patient returned to having all donor T-cells. At a median follow-up of 12 months, minimal residual disease was present in 18 of 22 patients with mixed T-cell chimerism and in 3 of 10 patients with full donor chimerism. The actuarial molecular relapse rate at 24 months for the two groups is 91% and 33%, respectively (P < .02). The finding of BCR- ABL mRNA within the first 6 months of transplant or on two consecutive assays was highly predictive of subsequent cytogenetic or hematologic relapse (P = .032 and P < .02, respectively). Ten patients, 9 with mixed T-cell chimerism, have relapsed (4 clinical, 6 cytogenetic) at a median of 12 months post-BMT. These data suggest that mixed T-cell chimerism may be a marker for abrogation of graft-versus-leukemia activity that is thought to be pivotal in eradicating minimal residual disease after BMT for CML.     

Delayed activation of quiescent donor hematopoietic stem cells in the host marrow cavity by anti-host monoclonal antibody

To understand the mechanisms controlling hematopoietic engraftment in untreated, normal recipients, we investigated the fate of parental, donor hematopoietic stem cells after apparent graft failures in unconditioned F1 hybrid recipient mice. By administering an anti-host H- 2K monoclonal antibody, which targets host cells but spares the donor, we found that chimerism could be induced by delayed conditioning in animals with apparent graft failure. Engraftment kinetics in the host were followed by typing individual colony forming unit-- granulocyte/macrophage (CFU-GM) colonies for their origin and showed that parental cells, which were otherwise virtually absent, become promptly detectable within the marrow cavity after antibody administration. Marrow transfers to secondary hosts suggested that parental stem cells were present in the marrow of the untreated recipients. These findings establish that the elimination of all parental cells cannot account for the absence of peripheral blood chimerism in the unconditioned F1 hybrid recipient. Thus, viable and functional donor stem cells, which remain quiescent in the host marrow, can be activated by a selective conditioning regimen and can rescue an apparent graft failure. The selective activation in vivo of marked stem cells in an unirradiated microenvironment may be a useful system to study the regulation of cellular proliferation within the marrow cavity.     

One hundred patients with acute leukemia treated by chemotherapy, total body irradiation, and allogeneic marrow transplantation.

One hundred patients, 54 with acute myelogenous leukemia (AML) and 46 with acute lymphoblastic leukemia (ALL), considered to be in the end stages of their disease, after combination chemotherapy were treated by marrow transplantation. All patients were given a marrow graft from an HLA-identical sibling after receiving 1000-rad total body irradiation (TBI). One group of 43 patients was given cyclophosphamide (CY), 60 mg/kg on each of 2 days, 5 and 4 days before TBI. In a second group of 31 patients, additional chemotherapy was given before CY and TBI. In a third group of 19 patients, BCNU was given before CY and TBI. A fourth group of 7 patients received other chemotherapy regimens before TBI. Six patients died 3-17 days after marrow infusion without evidence of engraftment. Ninety-four patients were engrafted and only one patient rejected the graft. Thirteen patients are alive with a marrow graft, on no maintenance antileukemic therapy, and without recurrent leukemia 1-4 1/2 yr after transplantation. Three have chronic graft-versus-host disease (GVHD). Four patients are alive 1 1/2 - 3 1/2 yr after grafting but have had a relapse of their leukemia. Of 93 evaluable patients, 19 did not develop GVHD and 24 developed very mild GVHD. Fifty patients developed moderate to severe GVHD, and 40 of these were treated with antithymocyte globulin. Interstitial pneumonia occurred in 54 patients and was the primary cause of death in 34. Interstitial pneumonia often occurred in association with GVHD and the most common etiologic agent was cytomegalovirus. A total of 31 patients have had a relapse of leukemia. There was no definite correlation between relapse of leukemia and the presence or absence of GVHD. The relapse rate appeared to be relatively constant over the first 2 yr and was extremely low after that time. Neither survival nor leukemic relapse appeared to be influenced by the type of leukemia nor by the preparative chemotherapy regimen given before TBI. Patients in fair clinical condition at the time of transplantation showed significantly longer survival times than patients in poor condition (p = 0.001). This observation, coupled with the observation that some patients may be cured of their disease, indicates that marrow transplantation should now be undertaken earlier in the management of patients with acute leukemia who have an HLA-matched sibling marrow donor.     

Hematopoietic donor chimerism and graft-versus-myeloma effect in relapse of multiple myeloma after allogeneic bone marrow transplantation

 A large group of patients relapsing after allogeneic bone marrow transplantation (BMT) have obtained remission after infusion of leukocytes from their original donor, suggesting a graft-versus-myeloma effect. However, side effects such as graft-versus-host disease and myelosuppression are severe, and sometimes fatal, complications of this therapeutic approach. Previously we demonstrated that patients with leukemia who lack donor hematopoiesis in relapse after BMT experience severe and lasting aplasia after infusion of donor leukocytes. In two patients – one with extramedullary and one with marrow relapse after a sex-mismatched transplantation – we analyzed hematopoietic chimerism by cell sorting and bone marrow cultures. CD34-positive cells, CD4-CD8-positive cells, committed progenitors, and LTC-IC were of donor origin, as demonstrated by two-color fluorescence in situ hybridization (FISH). Additionally, in relapse complete donor T-cell chimerism was seen. In contrast, plasma cells were of recipient origin in the patient who had a relapse in the bone marrow. Both patients were treated with infusions of donor leukocytes from their original donor. Neither patient suffered myelosuppression, and one achieved a stable complete remission. Received: February 26, 1999 / Accepted: April 14, 1999     

Leukemic cell colony formation in soft agar by bone marrow cells and peripheral blood cells from untreated acute leukemia patients

An in vitro culture technique for colony formation of marrow cells and peripheral blood cells from untreated acute leukemia patients and from patients in relapse is described. The colonies from bone marrow cells of an untreated acute myelogenous leukemia (AML) patient were demonstrated to be of leukemic origin by cytogenetic analysis. Cells obtained from colonies of leukemic origin contained the human malignancy-associated nucleolar antigen (HMNA) as detected by indirect immunofluorescence. This nucleolar antigen was not present in marrow or peripheral blood cells or cells from colonies of marrow from hematologically normal individuals. Colonies could be grown from over 70% of the marrow and peripheral blood samples from untreated acute leukemia patients. The median number of colonies obtained was 75 per 10(5) marrow cells from patients with AML. In 1/3 of the cases an increased number of colonies could be grown from marrow cell suspensions kept in liquid culture for 5 days. This is indicative of the proliferative capacity of the colony forming cell population. This assay may be useful for detection of residual clonogenic leukemic cells in marrow and peripheral blood cell suspensions.     

Allogeneic marrow transplantation for acute nonlymphoblastic leukemia after first relapse

Sixty-two patients with acute nonlymphoblastic leukemia in first relapse or second remission were treated with allogeneic marrow transplantation from HLA-matched siblings. In 17 patients (group 1), no attempt at reinduction of remission was made prior to transplantation. In 20 patients (group 2), attempts at inducing a second remission prior to transplantation were unsuccessful; and in 25 patients (group 3), a second remission was achieved. Five of 17 patients (29%) in group 1, 2 of 20 (10%) in group 2, and 5 of 25 (20%) in group 3 are surviving disease-free 2-6 yr after grafting. Early mortality from nonleukemic causes was equal in the 3 groups, but the risk of recurrent leukemia after transplantation was less in patients transplanted without attempts at reinduction (group 1). Among patients transplanted in relapse, those in early relapse (less than 30% blast cells in the marrow) appeared to do better than patients in florid relapse. The results obtained in group 1 are as good as or better than those achieved in patients transplanted in second or subsequent remission. Thus, for patients with acute nonlymphoblastic leukemia not transplanted in first remission, the optimal time for transplantation would appear to be as soon as possible after the first relapse.     

Chromosomal studies after bone marrow transplantation for leukaemia in children

Chromosomal studies were performed on 114 blood samples and 117 bone marrow samples, taken systematically over a period of 4 months after bone marrow transplantation (BMT) in 42 children grafted for acute lymphoblastic leukaemia (ALL) (n = 20), acute myeloid leukaemia (AML) (n = 16), non-Hodgkin's lymphoma (NHL) (n = 2) and myelodysplastic syndrome (MDS) (n = 4). In some cases, follow-up investigations were performed. In the first 4 months following BMT, mixed chimerism was frequently observed in blood of AML (25%), ALL (30%), NHL (100%) cases and in bone marrow samples of ALL (35%). The presence and relative number of a patient's own metaphases found shortly after transplantation was not related to leukaemia relapse and probably represents residual non-malignant haematopoietic precursor cells of the host. In only one child grafted for MDS with 45,XY, -7 karyotype was the marker clone still detectable in bone marrow at day +437 post-BMT. This patient shows no recurrence of the MDS and has a sustained haematological recovery at the time of writing, i.e. 4.5 years post-BMT. In 11 other patients, various structural chromosomal abnormalities (not related to the original leukaemia) were found in both peripheral blood and bone marrow. In three different patients structural anomalies were also found in bone marrow and blood samples from donor-derived cells. This indicates that, besides irradiation, there are other as yet unidentified factors (e.g. drugs), which are capable of inducing chromosomal anomalies in the post-BMT period.     

Cytogenetic analysis of chimerism and leukemia relapse in chronic myelogenous leukemia patients after T cell-depleted bone marrow transplantation

Serial cytogenetic studies were performed on 64 patients with chronic myelogenous leukemia (CML) after T cell-depleted allogeneic bone marrow transplantation (BMT). Forty patients with CML in chronic phase (CP) received cytoreduction followed by BMT with HLA-matched T cell-depleted allogeneic marrow. The remaining 24 patients were transplanted in second chronic, accelerated, or blastic phase, or received T cell-depleted grafts with a dose of T cells added back. The Y chromosome and autosomal heteromorphisms were used to distinguish between donor and host cells. Mixed hematopoietic chimerism (presence of donor and host cells) was identified in 90% of patients in first CP. The Philadelphia (Ph) chromosome reappeared in 16 of the 40 first CP CML patients. As expected, patients who had detectable Ph chromosome positive cells at any time during the posttransplant period had a high likelihood of subsequent clinical relapse. Transient disappearance of the Ph positive clone was rarely observed, and was followed by reappearance of the Ph chromosome or clinical relapse. A subset of engrafted patients with greater than 25% host cells within 3 months post-BMT had a significantly shorter survival time free of cytogenetic or clinical relapse compared with other patients. In patients who had received donor T cells added to the T cell-depleted graft, there was a higher proportion of complete chimerism. Clonal progression of Ph positive as well as negative cells was observed and may be the result of radiation induced breakage. Serial cytogenetic studies of patients post-BMT can provide useful information regarding the biologic and clinical behavior of CML.     

CD34+ marrow cells, devoid of T and B lymphocytes, reconstitute stable lymphopoiesis and myelopoiesis in lethally irradiated allogeneic baboons.

CD34+ cells devoid of detectable mature and immature T and B lymphocytes, expressing the CD2, CD10, and CD20 antigens, were isolated from marrows of three pairs of sex-mismatched, mixed lymphocyte culture (MLC) nonreactive, sibling baboons. Reciprocal transplants were performed between members of each pair, using the sex chromosomes, identified by standard cytogenetic techniques, as markers of the transplanted cells. Five animals from these three pairs were transplanted with 0.6 to 2.1 x 10(6)/kg of isolated cryopreserved and/or fresh isolated cells that were greater than 95% to 97% CD34+. Before transplantation, animals were treated with either single (920 or 1,020 cGy) or split (700 cGy x 2) dose total body irradiation. All animals engrafted with donor cells, as demonstrated by cytogenetic analysis of bone marrow metaphase cells 4 weeks after transplantation, with days to white blood cell count (WBC) greater than 500 being 19 +/- 2, to WBC greater than 1,000 23 +/- 2, to absolute neutrophil count greater than 500 24 +/- 3, and to platelets greater than 20,000 30 +/- 7. Three animals died of infectious-related complications at 34, 42, and 109 days after transplantation with evidence of host and donor cells (mixed chimerism) in marrow. Two animals remain alive and healthy more than 545 and 455 days after transplantation with stable mixed chimerism in marrow and blood. For these two animals, cytogenetic analysis of granulocyte/macrophage and erythroid colonies derived from marrow precursors between weeks 25 and 42 posttransplant showed evidence of mixed chimerism. Cytogenetic studies of CD2+ T cells and CD20+ B cells isolated from blood of these two animals between weeks 21 and 51 posttransplant showed the presence of mixed chimerism in both lymphocyte populations. Thus, isolated allogeneic CD34+ marrow cells devoid of detectable mature and immature T and B lymphocytes can engraft and reconstitute stable long-term myelopoiesis and lymphopoiesis in lethally irradiated baboons. These results are consistent with the hypothesis that CD34+ marrow cells contain pluripotent hematopoietic stem cells capable of fully reconstituting lymphohematopoiesis in the transplanted host.     

An approach for the analysis of relapse and marrow reconstitution after autologous marrow transplantation using retrovirus-mediated gene transfer.

Autologous bone marrow transplantation (ABMT) is widely used as treatment for malignant disease. Although the major cause of treatment failure is relapse, it is unknown if this arises entirely because of residual disease in the patient or whether contaminating cells in the rescuing marrow contribute. Attempts to purge marrow of its putative residual malignant cells may delay hematopoietic reconstitution and are of uncertain efficacy. We now describe how retrovirus-mediated gene transfer may be used to elucidate the source of relapse after ABMT for acute myeloid leukemia and to evaluate the efficacy of purging. Clonogenic myeloid leukemic blast cells in patient marrow can be transduced with the NeoR gene-containing helper-free retrovirus, LNL6, with an efficacy of 0% to 23.5% (mean, 10.5%). Transduced colonies grow in selective media and the presence of the marker gene can be confirmed in individual malignant colonies by polymerase chain reaction. If such malignant cells remain in harvested "remission" marrow, they will therefore be marked after exposure to LNL6. Detection of the marker gene in the malignant cells present at any later relapse would be firm evidence that residual disease contributed to disease recurrence, and would permit rapid subsequent evaluation of purging techniques. The technique also marks normal marrow progenitors from patients with acute myeloblastic leukemia. These colony-forming cells can be detected in long-term marrow cultures at a frequency of 1% to 18% for up to 10 weeks after exposure to the vector. Animal models and analysis of probability tables both suggest that these levels of marking in vitro are sufficient to provide information about the mechanisms of relapse and the biology of marrow regeneration in vivo. These preclinical data form part of the basis for current clinical studies of gene transfer into marrow before ABMT.     

Selective depletion of CD8+ T lymphocytes for prevention of graft-versus-host disease after allogeneic bone marrow transplantation

The effects of selectively depleting CD8+ cells from donor bone marrow were assessed in 36 patients receiving transplantation from an HLA-identical sibling as treatment for leukemia. Donor bone marrow underwent ex vivo treatment using anti-Leu-2 monoclonal antibody and complement. Patients received cyclosporine post-transplant for 6 months. Thirty-three patients had initial engraftment. Three failed to have hematologic recovery, and one patient with initial engraftment had late graft failure. The actuarial incidence of grade greater than or equal to 2 acute graft-versus-host disease was 28% +/- 18% and was usually confined to the skin. Of 33 patients with engraftment, 32 were complete chimeras and one had mixed chimerism. The tempo of hematologic and immunologic recovery was comparable with that reported with transplantation of unmodified bone marrow, although CD4+ and CD8+ T cells recovered at comparable rates. The actuarial rate of leukemia relapse was 11% +/- 10%, occurring in three patients with acute leukemia but in none of 13 patients transplanted for chronic myelogenous leukemia. Actuarial survival was 57% +/- 17% at 2 years. These data indicate that after transplantation of marrow depleted of CD8+ cells, engraftment with prompt hematologic and immunologic recovery generally occurs, with a relatively low rate of acute graft-versus-host disease. Graft failure remains a problem despite retention of CD4+ cells within the donor marrow. The lack of leukemia relapse in patients with chronic myelogenous leukemia suggests retention of a graft-versus-leukemia effect, at least for this malignancy.     

Chimerism studies using in situ hybridization for the Y chromosome after T cell-depleted bone marrow transplantation

In situ hybridization for the Y chromosome (Y-ISH) was used to monitor engraftment in 10 patients with hematological malignancies who had received T cell-depleted marrow transplants from sex-mismatched donors, seven of whom were only partially HLA-matched. In the three patients who engrafted, as the peripheral counts rose, the percentage of host peripheral blood and marrow mononuclear cells decreased steadily, although host cells (less than 1%) could still be detected as late as day 252. The percentage of host granulocytes fell rapidly to less than 0.2%. Seven patients did not achieve full engraftment by day 28. Those with a low percentage of host cells (less than 1%) improved with observation or treatment with steroids, while those with a high or increasing percentage of host cells did not improve even after treatment with GM-CSF or with repeat marrow infusion without reconditioning. In one patient with graft failure, the residual host cells were predominantly CD8+ CD57+ and CD3+ CD56+, phenotypes consistent with non-MHC-restricted cytotoxic T cells. Lack of full engraftment in recipients of T cell-depleted marrow is not always associated with autologous reconstitution and does not always require retransplantation. Y-ISH may be useful for monitoring patients at high risk for graft failure in order to detect adverse trends in mixed chimerism that will alter therapy early after transplantation.     

A murine model of antimetabolite-based, submyeloablative conditioning for bone marrow transplantation: biologic insights and potential applications

OBJECTIVE: Nonmyeloablative conditioning regimens for marrow transplantation are desirable in many settings. Because repeated doses of the antimetabolite 5-fluorouracil (5-FU) decreases marrow long-term repopulating ability (LTRA) upon transplantation into lethally irradiated hosts, we hypothesized that mice given sequential doses of 5-FU (termed paired dose 5-FU) may permit substantial syngeneic marrow engraftment. METHODS: C57Bl/6 or X-linked chronic granulomatous disease (X-CGD) mice were administered 5-FU (150 mg/kg) on days -5 and -1. Assessment of host marrow phenotype and repopulating ability occurred on day 0. Transplantation of syngeneic donor marrow occurred on day 0 or day +15. RESULTS: We confirmed that the number of Sca-1+lin- cells and the LTRA of marrow from paired dose 5-FU-treated animals were diminished. C57Bl/6 hosts conditioned with paired doses of 5-FU followed by transplantation of 20 x 10(6) fresh B6.SJL marrow cells on day 0 displayed 44.9% +/- 7.1% donor chimerism 2 months posttransplant, and 34.4% +/- 8.6% donor chimerism 6 months posttransplant. In contrast, paired dose 5-FU-conditioned hosts transplanted with similar numbers of donor cells on day +15 exhibited only 3.4% +/- 1.2% donor chimerism at 2 months. Paired dose 5-FU-conditioned X-CGD hosts transplanted with MSCV-m91Neo-transduced X-CGD marrow averaged 6.6% +/- 2.3% (range, 4%-10%) NADPH oxidase-reconstituted neutrophils 12-16 months after transplant. CONCLUSION: These findings support the concept that impairment of host stem cell competitiveness may be an important mechanism for permitting engraftment of donor cells, and suggest that only a brief period of modest host stem cell impairment may be necessary to achieve substantial donor cell engraftment.