Robert L. Truitt

Successful Allogeneic Transplantation of T-Cell–Depleted Bone Marrow from Closely HLA-Matched Unrelated Donors

We describe a four-year experience with bone marrow transplantation involving closely HLA-matched unrelated donors and 55 consecutive patients with hematologic disease who were seven months to 48.6 years old (median, 18 years). An intensive pretransplantation conditioning regimen and graft-versus-host disease (GVHD) prophylaxis with CD3-directed T-cell depletion and cyclosporine were employed. Durable engraftment was achieved in 50 of 53 patients who could be evaluated (94 percent; 95 percent confidence interval, 83 to 98 percent). Acute GVHD of Grade II to IV developed in 46 percent of the patients (confidence interval, 27 to 66 percent). The incidence and severity of acute GVHD were increased in recipients of HLA-mismatched marrow as compared with recipients of phenotypically matched marrow (incidence of 53 percent [confidence interval, 37 to 68 percent] vs. 17 percent [confidence interval, 5 to 45 percent]; P less than 0.05). Extensive chronic GVHD and deaths not due to relapse also tended to be more frequent when HLA-mismatched marrow was used, but not significantly so. With a median follow-up of more than 19 months (range, greater than 9 to greater than 39), the actuarial disease-free survival of transplant recipients with leukemia and a relatively good prognosis (acute leukemia in first remission and chronic myelogenous leukemia in chronic phase) was 48 percent (confidence interval, 24 to 73 percent), and that of recipients with more aggressive leukemia was 32 percent (confidence interval, 18 to 51 percent); the actuarial survival of recipients with non-neoplastic disease was 63 percent (confidence interval, 31 to 86 percent). We conclude that marrow transplantation with closely HLA-matched unrelated donors can be effective treatment for neoplastic and non-neoplastic diseases. Although transplants from phenotypically HLA-matched unrelated donors appear to be most effective, transplants with limited HLA disparity can also be successful in some patients.

Unrelated donor bone marrow transplantation to treat severe aplastic anaemia in children and young adults

Alternative donor bone marrow transplantation (BMT) to treat severe aplastic anaemia (SAA) in children and young adults has been complicated by high rates of graft rejection and severe graft‐versus‐host disease (GVHD). We hypothesized that increased immunosuppression combined with T‐cell depletion of the marrow graft would enable successful use of unrelated donor BMT in this disease. Preconditioning consisted of cytosine arabinoside, cyclophosphamide, and total body irradiation (TBI). T‐cell depletion was with the anti‐CD3 antibody T10B9. GVHD prophylaxis consisted of cyclosporine A. 28 previously transfused patients were transplanted. Nine donor/recipient pairs were HLA matched. As of 1 January 1996, 15/28 (54%) patients are alive, transfusion independent and well with a range of follow‐up of 13 months to 8 years (median 2.75 years). Fatalities include all three patients with non‐engraftment and all three patients with grade III/IV GVHD. Other fatalities were due to infections or therapy‐related toxicity. The incidence ≥ grade II acute GVHD was 28%. These data show that in children with SAA who have failed immunosuppression, unrelated donor BMT offers a reasonable hope of long‐term survival.

A decrease in graft-vs.-host disease without loss of graft-vs.-leukemia reactivity after MHC-matched bone marrow transplantation by selective depletion of donor NK cells in vivo

It is thought that natural killer cells may play a role in graft-vs.-host reactions after allogeneic bone marrow transplantation, but the use of NK cell-specific reagents has been limited. In this report, an NK allele-specific monoclonal antibody, anti-NK 1.1, was used to study the impact of in vivo donor NK cell depletion on GVH disease, graft-vs.-leukemia (GVL) reactivity and donor T cell chimerism after allogeneic murine BMT. AKR/J (H-2k) recipient mice were preconditioned with suboptimal irradiation (9 Gy = LD50) and transplanted with major histocompatibility complex-matched B10.BR (H-2k) BM cells with or without added spleen cells as a source of T cells. The addition of increasing numbers of spleen cells to the BM inoculum produced GVHD of varying intensities. The beneficial effect of NK depletion on GVHD was dependent on the intensity of the GVH reaction. Donor NK cell depletion had no effect on the survival of mice with severe GVHD after MHC-matched BMT (B10.BR into AKR) or after MHC-mismatched BMT (B10.BR into DBA/2; H-2k into H-2d). However, donor NK depletion increased survival of AKR hosts given sufficient B10.BR splenic T cells to induce mild-to-moderate GVHD. Ex vivo depletion of donor CD8+ T cells also reduced GVH-associated mortality, but the use of both CD8 and NK depletion offered no improvement over either alone, suggesting an interaction between CD8+ and NK 1.1+ cells. In contrast to CD8 depletion, donor NK depletion did not compromise the rapid and complete establishment of donor T cell chimerism nor the ability of chimeras to mount an effective GVL reaction. Thus, elimination of donor NK cells provides an alternate strategy for reducing GVHD without loss of GVL reactivity following MHC-matched allogeneic BMT.

Manipulation of graft-versus-host disease for a graft-versus-leukemia effect after allogeneic bone marrow transplantation in AKR mice with spontaneous leukemia/lymphoma.

Graft-versus-host (GVH) disease can result in a beneficial graft-versus leukemia (GVL) effect after bone marrow transplantation in patients with malignant disease. In this report, we used bacteria-free AKR (H-2k) mice bearing advanced spontaneous T cell leukemia/lymphoma as a moel to evaluate the GVH and GVL effects of bone marrow transplantation using fully incompatible SJL (H-2k) donors. A therapeutic GVL effec, accompanied by increased leukemia-free survival, was obtained only when 0.5x106 allogeneic lymphocytes (lymph node cells) were added to the marrow inoculum. Transplantation of allogeneic bone marrow without added lymph node cells (or use of syngeneic cells) resulted in a significant increase in leukemia relapse; increasing the dose of allogeneic lymph node cells to 2.0x106 resulted in significantly higher GVH-associated mortality. Survival and therapeutic benefits were obtained only when the intensity of the GVH reaction was carefully controlled by manipulation of alloreactive lymphocytes present in the marrow. These results suggest, indirectly, that T cell depletion may abolish any GVL effect of marrow transplantation, even if the donor is mismatched with the host at the major histocompatibility complex. The frequency in the spleen of cytotoxic T lymphocytes (CTL) reactive against host alloantigens was estimated using limiting-dilution microcytotoxicity assays at various times after transplantation of allogeneic bone marrow with and without added lymph node cells. The average frequency of CTL was highest in mice that were given marrow plus lymph node cells and tested within the first four weeks after transplantation. The level of CTL activity measured in vitro was dependent on the dose of lymphocytes injected and correlated with both the GVL and GVH effects in vivo. Down-regulation of CTL activity against host, but not third-party, alloantigens in vitro was observed under limiting dilution assay conditions, leading to the suggestion that host-specific regulatory cells may be present in these allogeneic bone marrow chimeras.

Rapamycin enriches for CD4+ CD25+ CD27+ Foxp3+ regulatory T cells in ex vivo-expanded CD25-enriched products from healthy donors and patients with multiple sclerosis

BACKGROUND CD4(+) CD25(bright+) regulatory T cells (Treg) can be expanded to clinical doses using CD3/CD28 Ab-coated beads plus IL-2. However, this method requires high purity of the starting population to prevent overgrowth by non-regulatory T cells. Rapamycin, an agent that inhibits T-cell proliferation but selectively spares Treg, may be a means to expand Treg from less pure CD25-enriched cells. METHODS CD25-enriched cells were prepared by a single-step immunomagnetic-selection using anti-CD25 microbeads. The cells were activated with a single addition of anti-CD3/CD28 beads and expanded in ex vivo 15-5% HS and autologous CD4(+) CD25(-) feeder cells,+/-rapamycin (0.01-20 ng/mL). IL-2 was added on day 3. Cells were rested for 2 days in ex vivo 15-5% HS and tested for phenotype, intracellular Foxp3 protein and suppressor activity. RESULTS In the absence of rapamycin, CD25-enriched fractions expanded >17 000-fold by 21 days. Although suppressor activity was detected to day 14, it declined significantly by 21 days as non-regulatory cells expanded. The addition of rapamycin inhibited expansion of non-regulatory T cells at doses > or =1 ng/mL while increasing suppressor activity and the percentage of CD4(+) CD25(+) CD27(+) Foxp3(+) cells. Rapamycin did not enrich for Foxp3(+) cells in expanded cultures of CD4(+) CD25(-) cells. Treg were also readily expanded in cultures of CD25-enriched cells obtained from patients with multiple sclerosis in the presence of rapamycin. DISCUSSION The addition of 1-20 ng/mL rapamycin to CD25-enriched cultures increased the purity of cells with the phenotype and function of Treg. This approach may alleviate the need for rigorous enrichment of Treg prior to activation and expansion for potential clinical use.

The Graft-Versus-Leukemia Effect of Post-transplant Donor Leukocyte Infusion

Tumor relapse remains a major obstacle to the success of allogeneic bone marrow transplantation (BMT) as a treatment for leukemia. Due to limited treatment options, the outlook for most patients that relapse following allogeneic BMT has been poor. The infusion of normal immunocompetent leukocytes from the original marrow donor has become a promising new option for treating/preventing leukemia relapse in allogeneic BMT recipients. This form of treatment has often been referred to as donor leukocyte infusion (DLI) therapy. Our laboratory is using murine models of allogeneic BMT to address important unresolved issues regarding DLI therapy in an effort to make the treatment more effective. These include identification of the antileukemic effector cells, augmentation of the antileukemic effect, and understanding why graft-versus-host-disease (GVHD) is less severe than anticipated. This article reviews our work in murine models of DLI and introduces our current working hypotheses concerning DLI therapy.

Allogeneic bone marrow chimerism in germ-free mice. IV. Therapy of 'hodgkin's-like' reticulum cell sarcoma in sjl mice.

“Hodgkins-like” reticulum cell sarcoma develops spontaneously in most SJL mice. Germ-free and conventional SJL mice bearing advanced reticulum cell sarcoma were treated with X-irradiation and transplantation of bone marrow from SJL or C3H/He donors. The 120-day survival rate of germ-free mice receiving allogeneic bone marrow (70%) exceeded that of all control groups; more importantly, germ-free mice that survived more than 4 months after treatment with allogeneic cells had no evidence of neoplastic lesions when killed. The germ-free environment effectively prevented graft-versus-host disease that was lethal to conventional mice. The results of these experiments offer additional evidence that bone marrow transplantation can be used as a therapeutic tool for spontaneous murine neoplasms.

Reactivity of in-vitro-expanded alloimmune cytotoxic T lymphocytes and Qa-1-specific cytotoxic T lymphocytes against AKR leukemia in vivo

The ability of alloimmune spleen cells expanded in mixed leukocyte culture (MLC) and cloned cytotoxic T lymphocytes (CTL) to kill H-2-compatible leukemia in vivo was evaluated. In comparison with fresh alloimmune spleen cells, MLC-expanded cells had a significantly higher frequency of CTL reactive against leukemia targets in vitro. However, the reactivity of MLC-expanded cells against first-passage spontaneous AKR (H-2k) leukemia in vivo was significantly less than when an equivalent number of fresh alloimmune spleen cells was injected. Comparable antileukemia reactivity was observed in vivo only when the inoculum of MLC-expanded cells was 2–3-fold higher than that of fresh spleen cells. This relative ineffectiveness was attributed to the altered migration pattern of cultured cells in vivo. IL-2-dependent cloned CTL, specific for a normal lymphocyte antigen (Qa-1b) also present on leukemia cells, were derived from MLC-expanded cultures and tested in vivo. For cloned CTL, as with MLC-expanded cells, erradication of AKR leukemia in vivo was associated with the tissue distribution pattern of the injected effector cells. That is, an effective antileukemia reaction was achieved only in tissues in which effector and target proximity was maintained. Qa-1b-specific cloned CTL did not interfere with engraftment of autologous or allogeneic bone marrow in lethally irradiated host mice, nor did they cause any clinically evident graft-versus-host disease. These findings suggest that cloned CTL specific for a normal cell surface antigen with limited host tissue distribution, but present on tumor cells, could be used for adoptive immunotherapy, provided CTL and tumor cell proximity can be attained.

Characterization of a Murine NKT Cell Tumor Previously Described as an Acute Myelogenous Leukemia

C1498 is an atypical myeloid leukemia that originated in a C57BL/6 mouse and has been used as a model for acute myelogenous leukemia. In studies of the immune response to C1498, we found that this tumor contained mRNA encoding the canonical NKT cell receptor V β 8.2-V α 14J α 281. Although cell-surface phenotypic analysis showed C1498 to be negative for NK1.1, it expressed several other molecules associated with NKT cell populations, such as DX5, CD1d, CD69, CD44, CD45RB and B220. RT-PCR demonstrated that C1498 contained CD3 ϵ mRNA transcripts, but message was not found for CD4, CD8 α, or CD8 β. This indicates that C1498 falls within the double negative (CD4 − CD8 − ) NKT cell lineage. RNase protection analysis showed that C1498 expressed mRNA for IL-2, IL-15, and macrophage migration inhibitory factor (MIF). These findings suggest that C1498 should be re-classified as a NKT cell leukemia with atypical myeloid features. It may, therefore, be a novel cell line in which to study NKT cell development and serve as a model for human NKT cell malignancies.

Preservation of lymphokine-activated killer activity following T cell depletion of human bone marrow.

T cell depletion has decreased the incidence and severity of graft-versus-host disease following transplantation of allogeneic bone marrow. In the treatment of leukemia, decreased GVHD has often been associated with diminished antileukemia or graft-versus-leukemia (GVL) reactivity resulting in higher relapse rates. However, we have not seen a loss of the GVL effect following transplantation of marrow grafts depleted of CD3+ T cells. This suggests that non-T-cell effectors may play a role in preventing leukemic relapse. To study whether natural killer and lymphokine-activated killer (LAK) activity in BM was compromised by T cell depletion, the effect of T-cell-specific monoclonal antibodies against CD3 and CD6 determinants alone, or in combination, on the generation and expansion of NK/LAK cells was examined in vitro and compared to the effect of T depletion on mitogen-driven T cell proliferation. Limiting dilution analysis revealed that T depletion with CD3 and/or CD6 specific antibodies significantly reduced the number of proliferating T lymphocytes but did not significantly affect the frequency of cells able to expand and mediate LAK activity. Bone marrow, depleted of CD3+ or CD6+ T cells, generated levels of LAK activity equivalent to non-T-cell-depleted bone marrow following long-term culture in recombinant interleukin 2. CD3- NKH-1+ cells were the predominant population in rIL-2 expanded marrow cultures prior to transplant and in the peripheral blood of patients who had received a CD3-depleted marrow graft 21-65 days earlier. These studies show that it is possible to selectively reduce GVH-reactive T cells in allogeneic bone marrow while retaining non-T-effector cells with potential to mediate an antileukemia effect in vivo.