Role of Interferon (IFN)α in "Cocktails" for the Generation of (Leukemia-derived) Dendritic Cells (DCleu) From Blasts in Blood From Patients (pts) With Acute Myeloid Leukemia (AML) and the Induction of Antileukemic Reactions.

Strategies to stabilize remissions by specific elimination of residual acute myeloid leukemia (AML) blasts are needed. Leukemia-derived dendritic cell (DCleu/DC) generated from myeloid blasts improve antileukemic T-cell reactivity and install T-cell memory. Interferon (IFN)α-DC methods produce DCleu from chronic myeloid leukemia-patients (pts') blood. Various INFα-containing versus other DC methods were studied to produce DCleu (evaluated by flowcytometry) from AML-pts' blast-containing mononuclear (MNC) or whole blood (WB). After DCleu/DC stimulation in mixed lymphocyte cultures, T cells' potential to gain antileukemic cytotoxicity was studied and correlated with different DC methods and DCleu/DC counts. (1) Generation of DCleu/DC: (a) "IFN-GIT" [containing granulocyte macrophage-colony stimulating factor (GM-CSF)+IFNα+ tumor necrosis factor (TNF)-α] produced DC successfully (≥10% DC, ≥5% DCleu/cells) from AML-MNC (WB) in 54 (56%), "MCM-Mimic" in 76 (75%), "Picibanil" in 83 (64%), and "Calcium-ionophore" in 42 (67%) of cases. Proportions of DC subtypes in MNC (WB) were comparable with all DC methods, (b) IFNα combinations containing only GM-CSF+IFNα or only IFNα showed low efficiency to produce DCleu/DC from MNC (WB) compared with "IFN-GIT." (2) Antileukemic functionality: DCleu/DC-stimulated T cells showed improved leukemia cytotoxicity compared with blast cells or unstimulated T cells. The highest blast proliferation (=insufficient T cells) was seen with "IFN-GIT" DC-stimulated T cells. Probability to respond to immunotherapy or to obtain blast lysis of DC-stimulated T cells correlated with high proportions of DCleu/DC after DC culture, independent of DC-generating methods. (3) Cytokine release profiles: levels of interleukin-6, IFN-γ, and interleukin-2 were significantly lower in DC culture supernatants (from MNC/WB) with "IFN-GIT" compared with "MCM," "Pici," and "Ca" DC supernatants. Our data show that (1) WB culture simulates AML-pts' in vivo situation, (2) DC generation is possible from AML-MNC (WB) with IFNα-containing and other DC methods, (3) successful IFNα-DC generation needs GM-CSF+IFNα+TNF-α (IFN-GIT); however, "IFN-GIT" produces less DCleu/DC compared with other (non-IFNα) DC methods, (4) T cells stimulated with "IFN-GIT"-produced DCleu/DC yielded comparable antileukemic cytotoxicity; however, in cases without achieved blast lysis, an increased blast proliferation was observed.

Paramunity-inducing Factors (PINDs) in dendritic cell (DC) cultures lead to impaired antileukemic functionality of DC-stimulated T-cells.

INTRODUCTION: Paramunity-inducing-Factors (PINDs) consist of attenuated/inactivated viruses of various poxvirus-genera, used in veterinary medicine as non-antigen-specific, non-immunising stimulators of the innate immune system against infectious and malignant diseases. Their danger-signaling-interactions were tested for their capacity to improve leukemic antigen-presentation on DC generated from AML-patients' blasts ('DCleu') and DC-stimulation/activation of antileukemic T-cells. METHODS: We analyzed, whether the addition of PINDs during DC cultures (15 healthy, 22 leukemic donors) and mixed lymphocyte culture (MLC, n = 15) with autologous (n = 6), allogeneic (n = 2) or T-cells after stem cell transplantation (SCT; n = 7) would alter the quality and quantity of DC, the composition of T-cell-subsets, and/or their antileukemic functionality (AF) as studied by FACS and functional Fluorolysis-cytotoxicity-assays. RESULTS: Effects on 1. DC-cultures: PINDs in DC-cultures lead to increased proportions of mature DC and DCleu, but reduced proportions of viable and overall, as well as TLR4- and TLR9-expressing DC. 2. MLC: PINDs increased early (CD8+) T-cell activation (CD69+), but reduced proportions of effector-T-cells after MLC 3. AF: Presence of PINDs in DC- and MLC-cultures reduced T-cells' as well as innate cells' antileukemic functionality. 4. Cytokine-release profile: Supernatants from PIND-treated DC- and MLC-cultures resembled an inhibitory microenvironment, correlating with impaired blast lysis. CONCLUSIONS: Our data shows that addition of PINDs to DC-cultures and MLC result in a "blast-protective-capacity" leading to impaired AF, likely due to changes in the composition of T-/innate effector cells and the induction of an inhibitory microenvironment. PINDs might be promising in treating infectious diseases, but cannot be recommended for the treatment of AML-patients due to their inhibitory influence on antileukemic functionality.

The Plant-Derived Naphthoquinone Droserone Inhibits In Vitro Measles Virus Infection.

The naphthoquinone droserone (1) is a natural product occurring in dicotyledonous plants. We have now observed that the addition of 1 during infection of tissue culture cells with measles virus considerably reduced the infection. Interestingly, the infection was inhibited only when droserone (1) was added during virus entry, but not when added to the cells prior to virus uptake or after virus uptake. These findings suggest that 1 interacts with viral particles to reduce infectivity. The formation of progeny measles virus particles was inhibited to 50 % by droserone (1) at a concentration (IC50) of approximately 2 µM with a half-maximal cytotoxicity (CC50) of about 60 µM for Vero cells. Other tested naphthoquinone derivatives, among them the likewise natural plumbagin (2), but also synthetic analogs, were either more cytotoxic or not as effective as 1. Thus, our data do not support the development of naphthoquinone derivatives into antiviral compounds, but suggest that they may be interesting research tools to study measles virus entry into cells.

Profiles of activation, differentiation-markers, or ß-integrins on T cells contribute to predict T cells' antileukemic responses after stimulation with leukemia-derived dendritic cells.

Stem cell transplantations and donor lymphocyte infusions are promising immunotherapies to cure acute myeloid leukemia (AML). Leukemia-derived dendritic cells are known to improve antileukemic functionality of T cells. We evaluated the composition and development of distinct T-cell subtypes in AML patients (n=12) compared with healthy probands (n=5) before and during stimulation with leukemia-derived dendritic cells-containing DC (DC) or blast-containing mononuclear cells (MNC) in 0-7 days mixed lymphocyte cultures (MLC) by flow cytometry. AML patients' T-cell subgroups were correlated with antileukemic functionality before and after DC/MNC stimulation by functional fluorolysis assays. (1) Unstimulated T cells from AML patients presented with significantly lower proportions of activated, Tcm, CD137, and ß-integrin T cells, and significantly higher proportions of Tnaive and Teff compared with healthy probands. (2) After 7 days of DC or MNC stimulation, T-cell profiles were characterized by (significantly) increased proportions of activated T cells with effector function and significantly decreased proportions of ß-integrin T cells. (3) Antileukemic cytotoxicity was achieved in 40% of T cells after MNC stimulation compared with 64% after DC stimulation. Antileukemic activity after DC stimulation but not after MNC stimulation correlated with higher proportions of Tcm and Tnaive before stimulation, as well as with significantly higher proportions of activated and ß-integrin T cells. Furthermore, cutoff values for defined T-cell activation/differentiation markers and ß-integrin T cells could be defined, allowing a prediction of antileukemic reactivity. We could demonstrate the potential of the composition of unstimulated/DC-stimulated T cells for the lysis of AML blasts. Especially, AML patients with high numbers of Tnaive and Tcm could benefit from DC stimulation; proportions of activated and ß-integrin T cells correlated with increased antileukemic functionality and could serve to predict T cells' reactivity during stimulation. Refined analyses in the context of responses to immunotherapies are required.

CD4(+)and CD8(+)T-cell reactions against leukemia-associated- or minor-histocompatibility-antigens in AML-patients after allogeneic SCT.

T-cells play an important role in the remission-maintenance in AML-patients (pts) after SCT, however the role of LAA- (WT1, PR1, PRAME) or minor-histocompatibility (mHag, HA1) antigen-specific CD4(+) and CD8(+)T-cells is not defined. A LAA/HA1-peptide/protein stimulation, cloning and monitoring strategy for specific CD8(+)/CD4(+)T-cells in AML-pts after SCT is given. Our results show that (1) LAA-peptide-specific CD8+T-cells are detectable in every AML-pt after SCT. CD8(+)T-cells, recognizing two different antigens detectable in 5 of 7 cases correlate with long-lasting remissions. Clonal TCR-Vß-restriction exemplarily proven by spectratyping in PRAME-specific CD8(+)T-cells; high PRAME-peptide-reactivity was CD4(+)-associated, as shown by IFN-γ-release. (2) Two types of antigen-presenting cells (APCs) were tested for presentation of LAA/HA1-proteins to CD4(+)T-cells: miniEBV-transduced lymphoblastoid cells (B-cell-source) and CD4-depleted MNC (source for B-cell/monocyte/DC). We provide a refined cloning-system for proliferating, CD40L(+)CD4(+)T-cells after LAA/HA1-stimulation. CD4(+)T-cells produced cytokines (GM-CSF, IFN-γ) upon exposure to LAA/HA1-stimulation until after at least 7 restimulations and demonstrated cytotoxic activity against naive blasts, but not fibroblasts. Antileukemic activity of unstimulated, stimulated or cloned CD4(+)T-cells correlated with defined T-cell-subtypes and the clinical course of the disease. In conclusion we provide immunological tools to enrich and monitor LAA/HA1-CD4(+)- and CD8(+)T-cells in AML-pts after SCT and generate data with relevant prognostic value. We were able to demonstrate the presence of LAA-peptide-specific CD8(+)T-cell clones in AML-pts after SCT. In addition, we were also able to enrich specific antileukemic reactive CD4(+)T-cells without GvH-reactivity upon repeated LAA/HA1-protein stimulation and limiting dilution cloning.

Antileukemic T-cell responses can be predicted by the composition of specific regulatory T-cell subpopulations.

Regulatory T cells (Treg) are important regulators of immune responses. In acute myeloid leukemia (AML) patients before/after immunotherapy (stem cell transplantation or donor lymphocyte infusion), their suppressive role can contribute to suppress severe graft-versus-host reactions, but also to impair antileukemic reactions. As leukemia-derived dendritic cells (DCleu) are known to improve the antileukemic functionality of T cells, we evaluated the composition and development of distinct Treg subtypes in AML patients (n=12) compared with healthy probands (n=5) under unstimulated conditions and during stimulation with DCleu-containing DC (DC) or blast-containing mononuclear cells (MNC) in 0- to 7-day mixed lymphocyte cultures by flow cytometry. T-cell subgroups in AML patients were correlated with antileukemic functionality before and after DC or MNC stimulation by functional fluorolysis assays. (1) AML patients' T cells presented with significantly higher frequencies of Treg subgroups in unstimulated T cells compared with healthy probands. (2) After 7 days of DC or MNC stimulation, all Treg subtypes generally increased; significantly higher frequencies of Treg subtypes were still found in AML patients. (3) Antileukemic cytotoxicity was achieved in 36% of T cells after MNC compared with 64% after DC stimulation. Antileukemic activity after DC but not after MNC stimulation correlated with significantly lower frequencies of Treg subtypes (CD8Treg/Teff/em reg). Furthermore, cut-off values for Treg subpopulations could be defined, allowing a prediction of antileukemic response. We demonstrate a crucial role of special Treg subtypes in the mediation of antileukemic functionality. High CD8 Treg, Teff/em reg, and CD39 T cells correlated clearly with a reduced antileukemic activity of T cells. DC stimulation of T cells contributes to overcome impaired antileukemic T-cell reactivity. Refined analyses in the context of clinical responses to immunotherapies and graft versus host reactions are required.