ALBERT

Description: Abstract 16 Immunization using tumor antigen-loaded dendritic cells (DC) holds promise for the adjuvant treatment of cancer to control residual disease. In a phase I/II trial, we investigated the effect of autologous DC vaccination in 17 patients with acute myeloid leukemia (AML) in remission but at high risk of full relapse. Wilms’ tumor 1 protein (WT1), a nearly universal tumor antigen, was chosen as an immunotherapeutic target because of its established role in leukemogenesis and superior immunogenic characteristics. Two out of 3 patients, who were in partial remission with morphologically demonstrable disease after chemotherapy, were brought into complete remission following 4 biweekly intradermal injections of WT1 mRNA-electroporated DC. In those 2 patients as well as in 7 other patients who were in complete remission but who had molecularly demonstrable residual disease, there was a return to normal of the AML-associated WT1 mRNA tumor marker following DC vaccination, compatible with clinical and molecular response in 9/17 patients. In 3 patients, the WT1 mRNA tumor marker returned to pathological values following normalization after initial DC vaccination and additional injections of DC were needed to bring back the tumor marker to normal. Of the 9 responders, 3 have relapsed and 2 have died. Of the 8 non-responders, 7 have relapsed and 7 have died. Of the 2 patients in partial remission who were brought into complete remission by the DC vaccination, 1 has relapsed and has died. Median overall survival was 52.0 months in responders as compared to 6.0 months in non-responders (P=0.0007). Median relapse-free survival was 47.0 months in responders and 3.0 months in non-responders (P smaller than 0.0001). Immunomonitoring performed on the first 10 patients, showed a significant increase in WT1-specific interferon-gamma+ CD8+ T cells and signs of general immune stimulation, such as a significant increase of plasma levels of interleukin 2 and of HLA-DR+ CD4+ T-cells. Clinical responses were correlated with elevated levels of activated natural killer cells post-vaccination. Long-term clinical responses, lasting for at least 3 years, were significantly correlated with an increase in polyepitope WT1-specific tetramer+ CD8+ T-cell frequencies. There was no significant change post-vaccination in WT1 antibody levels or of regulatory T lymphocytes. In conclusion, DC-based immunotherapy elicits both innate and adaptive cellular immune responses correlated with clinical benefit. WT1 mRNA-loaded DC emerge as a feasible and effective strategy to control residual disease in AML, in particular as a post-remission treatment to prevent full relapse. Disclosures: Berneman: Argos Therapeutics: Patents & Royalties. Van Tendeloo:Argos Therapeutics: Patents & Royalties.

Description: Abstract 2742 Molecular monitoring of BCR/ABL transcripts by real time quantitative reverse transcription PCR (qRT-PCR) is an essential technique for clinical management of patients with BCR/ABL-positive CML and ALL. Though quantitative BCR/ABL assays are performed in hundreds of laboratories worldwide, results among these laboratories cannot be reliably compared due to heterogeneity in test methods, data analysis, reporting, and lack of quantitative standards. Recent efforts towards standardization have been limited in scope. Aliquots of RNA were sent to clinical test centers worldwide in order to evaluate methods and reporting for e1a2, b2a2, and b3a2 transcript levels using their own qRT-PCR assays. Total RNA was isolated from tissue culture cells that expressed each of the different BCR/ABL transcripts. Serial log dilutions were prepared, ranging from 100 to 10−5, in RNA isolated from HL60 cells. Laboratories performed 5 independent qRT-PCR reactions for each sample type at each dilution. In addition, 15 qRT-PCR reactions of the 10−3 b3a2 RNA dilution were run to assess reproducibility within and between laboratories. Participants were asked to run the samples following their standard protocols and to report cycle threshold (Ct), quantitative values for BCR/ABL and housekeeping genes, and ratios of BCR/ABL to housekeeping genes for each sample RNA. Thirty-seven (n=37) participants have submitted qRT-PCR results for analysis (36, 37, and 34 labs generated data for b2a2, b3a2, and e1a2, respectively). The limit of detection for this study was defined as the lowest dilution that a Ct value could be detected for all 5 replicates. For b2a2, 15, 16, 4, and 1 lab(s) showed a limit of detection at the 10−5, 10−4, 10−3, and 10−2 dilutions, respectively. For b3a2, 20, 13, and 4 labs showed a limit of detection at the 10−5, 10−4, and 10−3 dilutions, respectively. For e1a2, 10, 21, 2, and 1 lab(s) showed a limit of detection at the 10−5, 10-4, 10-3, and 10-2 dilutions, respectively. Log %BCR/ABL ratio values provided a method for comparing results between the different laboratories for each BCR/ABL dilution series. Linear regression analysis revealed concordance among the majority of participant data over the 10-1 to 10-4 dilutions. The overall slope values showed comparable results among the majority of b2a2 (mean=0.939; median=0.9627; range (0.399 – 1.1872)), b3a2 (mean=0.925; median=0.922; range (0.625 – 1.140)), and e1a2 (mean=0.897; median=0.909; range (0.5174 – 1.138)) laboratory results (Fig. 1–3)). Thirty-four (n=34) out of the 37 laboratories reported Ct values for all 15 replicates and only those with a complete data set were included in the inter-lab calculations. Eleven laboratories either did not report their copy number data or used other reporting units such as nanograms or cell numbers; therefore, only 26 laboratories were included in the overall analysis of copy numbers. The median copy number was 348.4, with a range from 15.6 to 547,000 copies (approximately a 4.5 log difference); the median intra-lab %CV was 19.2% with a range from 4.2% to 82.6%. While our international performance evaluation using serially diluted RNA samples has reinforced the fact that heterogeneity exists among clinical laboratories, it has also demonstrated that performance within a laboratory is overall very consistent. Accordingly, the availability of defined BCR/ABL RNAs may facilitate the validation of all phases of quantitative BCR/ABL analysis and may be extremely useful as a tool for monitoring assay performance. Ongoing analyses of these materials, along with the development of additional control materials, may solidify consensus around their application in routine laboratory testing and possible integration in worldwide efforts to standardize quantitative BCR/ABL testing. Disclosure: Sher: Invivoscribe Technologies Inc: Employment. Miller:Invivoscribe Technologies Inc: Employment. Huang:Invivoscribe Technologies Inc: Employment. Shaw:Invivoscribe Technologies Inc: Employment.

Description: To date, Wilms’ tumor protein (WT1) is acknowledged as a valuable target for active specific immunotherapy in several solid and hematological malignancies, such as leukemia. Preclinical data from our laboratory and that of Hans Stauss have already shown that WT1 RNA-electroporated dendritic cells (DC) stimulate WT1-specific T cells in vitro (Van Driessche A et al. Leukemia2005;19:1863–1871). Therefore, we started a phase I/II dose-escalation trial in which patients with acute myeloid leukemia (AML) in remission received intradermal injections with WT1 RNA-loaded DC. Feasibility, safety and immunogenicity of the vaccine were investigated. Seven patients received four biweekly DC vaccines. A delayed-type hypersensitivity (DTH) test was performed 2 weeks following the last vaccination. Patients underwent an apheresis and monocytes were isolated using CD14-labeled magnetic beads by CliniMACS. DC were generated in 6-day cultures in clinical-grade medium supplemented with serum, GM-CSF and IL-4 and maturated with PGE2 and TNF-a. Keyhole limpet hemocyanin (KLH) was added during maturation as a CD4+ helper antigen. Mature DC were harvested, electroporated with WT1 mRNA and used as vaccines. Patients were monitored for minimal residual disease (MRD) by analyzing WT1 RNA expression in peripheral blood by qRT-PCR. When the patient was HLA-A2+, tetramer staining was performed to detect WT1-specific CD8+ T cells. Before and after the vaccination cycle, peripheral blood was collected for immunomonitoring purposes. There was successful DC generation and vaccine production in all patients selected. No serious adverse events or toxicity was seen and all vaccinations were well tolerated. A decrease in WT1 RNA expression was observed during the course of the vaccination in 3/5 patients who had an increased WT1 mRNA level in peripheral blood at the start of DC vaccination. A vaccine-specific immune response was demonstrated in 7/7 patients by an in vivo DTH reaction both to KLH as well as to WT1. By tetramer analysis, detectable levels of WT1-specific CD8+ T cells could be demonstrated during the course of the vaccination both in the peripheral blood as well as in the expanded DTH-infiltrating T cells from the skin biopsies. Preliminary data from immunomonitoring in pre- and post-vaccination T cell samples from 3 patients show a mixed T helper (Th)1/Th2 response towards the KLH and the WT1 protein following vaccination. We conclude that vaccination of AML remission patients with WT1 RNA-loaded DC is feasible and safe. Furthermore, the vaccine elicits anti-vaccine T-cell responses in vivo and a decrease in WT1 RNA expression levels was observed during MRD monitoring in some vaccinated patients.

Description: The Wilms’ tumor protein WT1 is a target for immunotherapy in malignancies, such as acute myeloid leukemia (AML). Following our demonstration that dendritic cells (DC) can be efficiently transfected by messenger (m)RNA electroporation (Van Tendeloo VF et al. Blood2001;98:49–56) and that WT1 mRNA-electroporated DC stimulate WT1-specific T cells in vitro (Van Driessche A et al. Leukemia2005;19:1863–1871), we performed a phase I/II dose-escalation trial, in which patients with AML in remission but at high risk of relapse and without a direct sib allo-transplant option (9 patients) or with slowly progressive AML (1 patient) received intradermal injections of WT1 RNA-loaded DC. Following apheresis and CD14 immunomagnetic monocyte separation, DC were generated in 6-day cultures in clinical-grade medium supplemented with serum, granulocytemacrophage colony-stimulating factor (GM-CSF) and interleukin (IL)-4, matured with prostaglandin (PG)E2 and tumor necrosis factor (TNF)-alpha, harvested, electroporated with WT1 mRNA and used as vaccines. The patients received four biweekly DC vaccines and a delayed-type hypersensitivity (DTH) test was performed 2 weeks following the last vaccination. Patients were monitored for minimal residual disease (MRD) by analyzing WT1 RNA expression in peripheral blood by quantitative reverse transcriptase polymerase chain reaction (qRT-PCR) (Cilloni D et al. Leukemia2002;16:2115–2121 & Cilloni D et al. Haematologica2008;93:921–924). Before and after vaccination, peripheral blood was collected for immunomonitoring purposes. Feasibility, safety, immunogenicity and effect on MRD were investigated. There was successful DC generation and vaccine production in all 10 patients. No serious adverse events or toxicity were observed and vaccinations were well tolerated. A decrease in WT1 RNA expression was observed during the course of the vaccination in 4/7 patients who had an increased WT1 mRNA level in peripheral blood. Three of those patients are still in complete hematological remission. An in vivo vaccine-specific immune response was demonstrated in 10/10 patients by DTH. Ex vivo immunomonitoring analysis showed a significant increase in circulating activated HLA-DR+ CD4+ T cells and in IL-2 plasma levels following vaccination. Importantly, in vitro restimulation assays of peripheral blood mononuclear cells revealed a significant postvaccination increase in interferon (IFN)-gamma-producing WT1-specific CD8+ T cells (n= 8 evaluable patients), but not in cytokine-producing WT1-specific CD4+ T cells. There was no significant change in WT1-specific antibodies following vaccination. We conclude that vaccination of AML patients with WT1 RNA-loaded DC is feasible and safe. Furthermore, the DC elicit vaccine-specific and WT1-specific CD8+ T-cell responses. The correlation between reduction of circulating WT1 mRNA and the administration of the DC vaccines strongly suggests that this DC vaccine elicits an antileukemic activity.