Brigitte Eibl

Generation of mature dendritic cells from human blood An improved method with special regard to clinical applicability

Two methods to generate human dendritic cells from hematopoietic precursor cells in peripheral blood have recently been published. One approach utilizes the rare CD34+ precursors and GM-CSF plus TNF-α. The other method makes use of the more abundant CD34− precursor population and GM-CSF plus IL-4. Here we report a method that is based on the latter approach. However, the GM-CSF and IL-4 treated cells are not stable mature dendritic cells, e.g., the characteristic morphology and nonadherence of dendritic cells is lost if the cytokines are removed. We describe the need for a monocyte-conditioned medium to generate fully mature and stable dendritic cells. This is achieved by adding a 3 day ‘maturation culture’ to the initial 6–7 day culture in the presence of GM-CSF and IL-4. Macrophage-conditioned medium contains the critical maturation factors. Mature dendritic cells are defined by their pronounced display of motile cytoplasmic processes (‘veils’), their high capacity to induce proliferative responses in resting T cells, particularly in naive umbilical cord T cells, their down-regulated antigen processing ability, and their characteristic phenotype: expression of CD83, high levels of MHC molecules and CD86, lack of CD115 and perinuclear dot-like CD68 staining. These features are stable for at least 3 days upon withdrawal of cytokines and conditioned media. IL-4 can be replaced by IL-13. When CD34+ progenitors are depleted from blood, there is only a minor reduction in the yield of dendritic cells by this method. We have adapted the method to consider several variables that are pertinent to clinical use, including a change from fetal calf serum to human plasma and to media approved for clinical use like X-VIVO or AIM-V. 1% plasma and RPMI 1640 are currently optimal. Additional reagents used for cell culture (Ig, cytokines) and cell separation (immunomagnetic beads) are approved for or already used in clinical applications. For 40 ml blood, the yield is 0.8–3.3 × 106 mature dendritic cells as defined by the expression of the new dendritic cell-restricted marker CD83. CD83+ cells constitute between 30 and 80% of all cells recovered at the end of the culture period. Yields can be enhanced up to six-fold if the blood donors are pretreated with G-CSF. Stable, mature dendritic cells generated by this method should be a powerful tool for active immunotherapy.

Dendritic cells generated from blood precursors of chronic myelogenous leukemia patients carry the Philadelphia translocation and can induce a CML-specific primary cytotoxic T-cell response.

Dendritic cells (DC) are professional antigen‐presenting cells specialized in the initiation of primary immune responses. We were interested to know whether mature DC can be grown in vitro from peripheral blood mononuclear cells (PBMC) of patients with chronic myelogenous leukemia (CML), and whether they carry the Philadelphia (Ph) translocation. Using a method recently described, DC were generated from PBMC precursors of 12 patients with CML using GM‐CSF, IL‐4, and monocyte‐conditioned medium. DC exhibited the typical morphology with thin cytoplasmatic processes and expressed high levels of MHC class II, CD86, and CD83 typical for mature DC. After sorting with the monoclonal antibody CD83, a cell population of more than 95% CD83 positive cells was obtained. The presence of the Ph translocation was analyzed in these cells, in PBMC, lymphoblastoid cell lines (LCL), and in phytohemagglutinin (PHA)‐induced T blasts from the same patients by fluorescence in situ hybridization (FISH). In contrast to all other cells analyzed, the vast majority of DC (95.9 ± 0.7%) displayed the Ph translocation, irrespective of disease stage or therapy. PBMC were predominantly positive for the Ph chromosome (67.6 ± 7.3%), whereas only 11.4 ± 1% of the B cells and 4.4 ± 1.1% of the PHA blasts carried the Ph translocation. Using such leukemic DC as antigen‐presenting cells, a primary CML‐directed cytotoxic immune response in vitro was obtained, as shown by the specific recognition of Ph chromosome positive cells. We conclude that DC can be generated from blood progenitors of CML patients in vitro and exhibit, to a large extent, the Ph translocation. Such DC, which in a preliminary experiment have been able to induce a primary CML‐directed cytotoxic immune response in vitro, might be ideal candidates for adoptive immunotherapy either by direct transfer of DC for in vivo generation of a T‐cell response or by in vitro generation of CML‐specific cytotoxic autologous or HLA‐matched normal T‐cell clones for use in vivo. Genes Chromosomes Cancer 20:215–223, 1997.

Immune response modulation by pentoxifylline in vitro.

Pentoxifylline (PTX) has recently been shown to modulate TNF-a production and to reduce the incidence and severity of all major complications after BMT, including mucositis, veno-occlusive disease, renal insufficiency, hypertension, and graft-versus-host disease. To analyze in detail the effect of PTX on immune complications after BMT, we investigated the immunomodulatory effect of PTX on immune responses in vitro. The continuous presence of PTX significantly reduced the proliferative response of PBMC to PHA stimulation and to alloantigens in a dose-dependent manner. Starting at concentrations of 100 μg/ml, PTX was able to inhibit and, at 1000 μg/ml, completely block mitogen-induced proliferation. Maximal inhibition of more than 90% (91 ± 4%) was also observed at PTX concentrations of 1000 μg/ml, in the mixed lymphocyte culture (MLR) and by addition on day 0. However, lower but still significant suppression (13 ± 7%) was achieved at concentrations of 10 μg/ml, PTX. The inhibitory capacity of PTX was increased by mAbs against TNF-a (34 ± 5% additional suppression at 100 us/ml PTX) and not reversed by the addition of rTNF-α. The effect of PTX on the generation of CTLs in vitro was studied in the cell-mediated lymphotoxicity assay. PTX (100 μg/ml) significantly inhibited (P = 0.0178) the in vitro generation of CTLs when PTX was added to the culture on day 0. PTX also showed profound modulatory properties in the NK assay, with a reduction of 23 ± 3% in specific lysis at 10 μg/ml PTX and maximal reductions of 88 ± 3% at 1000 μg/ml PTX. Immunomodulatory properties of PTX were not only associated with blockage of TNF-α, as shown by decreased mRNA expression and TNF-a values in the culture supernatants, but also with an impaired production of other cytokines and secondary messages such as IFN-γ and neopterin. PTX treatment, however, did not affect IFN-a or IL-1β production, and IL-6 release was even increased. PTX, therefore, has profound immunomodulatory properties in vitro, which are associated with selective inhibition of cytokine release and can be enhanced by the addition of mAbs against TNF-α, but not reversed by the addition of rTNF-α.

LST1: A Gene with Extensive Alternative Splicing and Immunomodulatory Function

The gene of the leukocyte-specific transcript (LST1) is encoded within the TNF region of the human MHC. The LST1 gene is constitutively expressed in leukocytes and dendritic cells, and it is characterized by extensive alternative splicing. We identified 7 different LST1 splice variants in PBMC; thus, 14 LST1 splice variants (LST1/A-LST1/N) have been detected in various cell types. These isoforms code for transmembrane as well as soluble LST1 proteins characterized by two alternative open reading frames at their 3′ end. We demonstrate the presence of the transmembrane variant LST1/C on the cell surface of the monocytic cell lines U937 and THP1. Recombinant expression of LST1/C permitted its profound inhibitory effect on lymphocyte proliferation to be observed. In contrast, the alternative transmembrane variant LST1/A, the extracellular domain of which shows no amino acid sequence homology to LST1/C exerted a weaker but similar inhibitory effect on PBMC. These data demonstrate the protein expression of LST1 on the cell surface of mononuclear cells, and they show an inhibitory effect on lymphocyte proliferation of two LST1 proteins although they have only a very short amino acid homology.

Serum levels of interleukin 6, interleukin 8, and C-reactive protein after human allogeneic bone marrow transplantation.

Serum levels of interleukin 6 (IL-6) and C-reactive protein (CRP) were measured every second day from day -6 to day +86 in 24 patients undergoing allogeneic (n = 23) and syngeneic (n = 1) bone marrow transplantation (BMT). Endogenous serum levels of IL-6, IL-8, and CRP were further analyzed during complications after BMT, such as fever of unknown origin (FUO), severe infectious complications and acute graft-versus-host disease (GVHD). In addition, CRP levels were measured in 10 patients with interstitial pneumonitis of various origins (CMV, idiopathic). In all 24 patients IL-6 and CRP levels showed a characteristic monophasic pattern. After a slight decrease in the first days after BMT, a significant increase was observed, starting on day +3/+5 (P < 0.05) and reaching peak levels on day +9/+11 (P < 0.01). CRP had a similar pattern, with an increase in serum levels on day +3/+5 and maximum levels one to three days after the IL-6 peak was reached. The magnitude of the peak was related to the development of complications in the further course of BMT and was high in patients with and low in patients without complications. Serum levels of both molecules returned to baseline after day 14 posttransplant. Increased IL-6 and CRP levels were observed in the further course of BMT during severe infections or FUO either on the day of clinical onset (IL-6) or three days later (CRP), but not during acute GVHD grade III/IV. CMV interstitial pneumonitis (CMV-IP) was accompanied by an increase in CRP levels, while no such elevations were observed in patients with idiopathic interstitial pneumonitis (IIP). Elevated IL-8 serum levels occurred during bacterial infections, but to a lesser amount also during GVHD and CMV-IP. In conclusion, a characteristic pattern of IL-6 and CRP was observed after allogeneic BMT and a further increase associated with infectious complications. Since no significant elevations were seen in patients with GVHD, we conclude that both molecules are not involved in the induction of GVHD and might be useful diagnostic tools for the prediction and diagnosis of infectious complications after BMT. In contrast, assessment of IL-8 serum values does not permit clinical complications to be specified.

Phenotypic and functional deficiencies of leukaemic dendritic cells from patients with chronic myeloid leukaemia.

Summary. Chronic myeloid leukaemia (CML) dendritic cells (DC) are possible candidates for inducing antileukaemic immunity. This study aimed to investigate the frequency, phenotype and function of blood‐derived leukaemic DC in comparison with DC from healthy donors using flow cytometric assays and mixed leucocyte reaction (MLR). Immature leukaemic DC displayed a reduced endocytotic capacity as compared with healthy controls. Moreover, in vitro maturation of leukaemic DC was found to be deficient. Expression of CD80, CD83, CD86, and major histocompatibility complex class I and class II antigens were reduced on lipopolysaccharide (LPS)‐matured leukaemic DC but were enhanced by a mixture of interleukin 1β (IL‐1β), IL‐6, tumour necrosis factor‐α (TNF‐α) and prostaglandin E2 (PGE2). Upon stimulation with bacterial LPS, intracellular TNF‐α and IL‐8 production was diminished in maturing DC from CML patients. This distinct cytokine deficiency was overcome when leukaemic DC were stimulated with cytokines/PGE2. MLR showed fully functional leukaemic DC after TNF‐α‐induced maturation, but a reduced proliferative alloresponse of leukaemic peripheral blood mononuclear cells. Further, intracellular production of cytokines in CML‐derived T cells was markedly reduced. These data indicated that, in CML, the maturation response of leukaemic monocyte‐derived DC to a natural stimulus like LPS is abnormal and may be caused by an aberrant TNF‐α response in these cells. Thus, TNF‐α alone or in combination with pro‐inflammatory and T‐cell stimulatory cytokines should be considered as an adjuvant for DC‐based immunotherapy in CML.

Survival after bone marrow transplantation from cytomegalovirus seropositive sibling donors

HLA-A2-restricted T cells show peptide-specific activity against cytomegalovirus and leukaemia cells. We retrospectively analysed the influence of donor cytomegalovirus serostatus on the outcome of 103 consecutive patients who had leukaemia and who received bone-marrow transplants from HLA-identical sibling donors. We found that donor cytomegalovirus seropositivity significantly improved overall survival (p=0.02) as a result of lower relapse incidence (p=0.035) in HLA-A2-positive but not HLA-A2-negative recipients. In HLA-A2-positive recipients donor cytomegalovirus seropositivity was associated with chronic graft-versus-host disease (GVHD), but even in patients without chronic GVHD donor cytomegalovirus seropositivity significantly improved survival (p=0.0483). These preliminary data provide evidence that at least in HLA-A2-positive recipients, transplantation of bone marrow from cytomegalovirus positive, HLA-identical sibling donors seems to be associated with substantial graft-versus-leukaemia activity, and suggests a cross-reactivity of cytomegalovirus-specific donor-derived cytotoxic T cells with HLA-A2-restricted recipient minor histocompatibility antigens.

In Vivo T Cell Depletion with Low-Dose Rabbit Antithymocyte Globulin Results in Low Transplant-Related Mortality and Low Relapse Incidence Following Unrelated Hematopoietic Stem Cell Transplantation

Stem cell transplantation from unrelated donors is associated with an increased risk of graft failure and graft-versus-host disease (GVHD). Addition of pretransplant antithymocyte globulin (ATG), although reducing the risk of graft rejection and GVHD, bears the risk of overimmunosuppression, resulting in an increased relapse rate and transplant-related mortality. Therefore, we evaluated in 21 consecutive patients receiving unrelated stem cell grafts from either HLA-matched (38%) or -mismatched (62%) donors whether low-dose rabbit ATG added to cyclosporin A and methotrexate at a total dose of 3.5 mg/kg for HLA-identical and 5.0 mg/kg for HLA-mismatched transplants given in two divided doses on days -2 and -1 provides sufficient immunosuppression for prevention of GVHD and graft rejection but is associated with an acceptable risk of relapse and transplant-related mortality. Stable leukocyte engraftment was achieved in all patients (100%). Overall survival after a median follow-up of 26 (median, range 14-42) months was 56 +/- 26% (95% confidence interval, CI) and the overall relapse rate at 3 years was 24 +/- 21%. Three-year survival for standard-risk patients, i.e., chronic myeloid leukemia (CML) in first chronic phase or acute leukemia in first complete remission, was 87% +/- 13% versus 40% +/- 31% for patients with more advanced disease. The incidence of acute GVHD II-IV degrees was 55 +/- 22%; that of severe acute GVHD III-IV degrees was 21 +/- 19%. Chronic GVHD was observed in 5/17 (29%) patients surviving more than 100 days post stem cell transplantation. Transplant-related mortality was 16 +/- 15% (95% CI) at day + 100 and 25 +/- 19% (95% CI) at 1 year after the transplant. The data presented show that pretransplant in vivo T cell depletion with low-dose rabbit ATG results in a low transplant-related mortality due to a low incidence of severe acute and chronic GVHD and a low relapse rate. To find out the optimal rabbit ATG dose in the unrelated stem cell transplantation setting, further dose-finding studies comparing high- and low-dose regimens are necessary.

Serum levels of cytokines and secondary messages after T-cell-depleted and non-T-cell-depleted bone marrow transplantation : Influence of Conditioning and hematopoietic reconstitution

Cytokines are increasingly recognized as important mediators of graft-versus-host disease (GVHD). Measurements of cytokine serum levels in patients with GVHD, and successful prevention and treatment of the disease with the use of cytokine antagonists to either the cytokine or its receptor, are only two of several factors demonstrating the involvement of cytokines in GVHD. To further investigate the role of cytokines in the pathomechanism of acute GVHD, we investigated endogenous serum levels of various cytokines and dependent molecules in sera of 14 patients after T-cell-depleted (TCD) bone marrow transplantation (BMT) and compared the results with those of 12 patients undergoing non-TCD BMT. The effect of various conditioning regimens and of hematopoietic reconstitution on cytokine serum levels was analyzed in detail in these cohorts of patients by measuring interferon (IFN)-gamma, IFN-alpha, tumor necrosis factor-alpha, interleukin-6, neopterin, and beta2-microglobulin. The analyses showed that an increase in IFN-gamma and neopterin serum levels was a specific feature of cyclophosphamide administration and was not observed after other cytostatic drugs or total body irradiation, and that an increase in IFN-gamma, neopterin, beta2-microglobulin, and IFN-alpha release depends on the presence of T cells in the graft. We conclude that significant cytokine serum alterations were noted after TCD BMT as compared with after non-TCD BMT. These alterations, besides depletion of cytotoxic effector cells, might be involved in preventing GVHD after TCD BMT. In addition, more attention should be devoted to the cytokine release-inducing capacity of the conditioning regimen, because such a release might influence the occurrence of transplant-related complications after BMT.

ENDOGENOUS INTERLEUKIN 1 RECEPTOR ANTAGONIST DURING HUMAN BONE MARROW TRANSPLANTATION: Increased Levels During Graft-versus-Host Disease, During Infectious Complications, and After Immunoglobulin Therapy1

In order to understand in more detail the role of endogenous interleukin 1 receptor antagonist (IL-1ra) during bone marrow transplantation, IL-1ra serum levels of 28 patients undergoing allogeneic (n=25) or autologous (n=3) bone marrow transplantation were measured with a commercially available ELISA. In addition, the impact of intravenous immunoglobulin (IVIG) was evaluated by analyzing IL-1ra serum levels before and 2, 5, and 24 hr after IVIG infusion. IL-1ra measurements revealed a nadir of circulating IL-1ra levels 3-5 days after bone marrow transplantation, with an increase during conditioning and hematological reconstitution. Circulating IL-1ra levels were significantly increased in patients with cytomegalovirus (CMV) disease, CMV reactivation, graft-versus-host disease (GVHD), or fever of unknown origin, when compared with time-matched controls without complications. Highest levels were observed in patients with CMV disease (1922+/-388 pg/ml), followed by patients with CMV reactivation (1575+/-435 pg/ml) and GVHD (1178+/-317 pg/ml). The magnitude of IL-1ra increase in GVHD was related to disease severity. Patients with grade III-IV GVHD developed higher IL-1ra levels than did patients with grade I-II GVHD. Lower but still significantly elevated IL-1ra levels were observed during fever of unknown origin (384+/-87 pg/ml). An increase of IL-1ra serum levels followed the administration of IVIG before transplantation and after hematopoietic reconstitution, but not during aplasia, pointing to the important role of hematopoietic cells in the production of IL-1ra. In conclusion, we show that IL-1ra release is related to conditioning regimen, hematopoietic reconstitution, complications of infectious and alloimmune etiology after bone marrow transplantation, and exogenously administered IVIG.