Your search keyword '"Gerty Schreibelt"' showing total 135 results

1. Design of TOLERANT: phase I/II safety assessment of intranodal administration of HSP70/mB29a self-peptide antigen-loaded autologous tolerogenic dendritic cells in patients with rheumatoid arthritis

Author

Jacob M van Laar, Anna de Goede, Gerty Schreibelt, Arie Jan Stoppelenburg, I Jolanda M de Vries, Paco Welsing, Bouke Koeneman, Evert-Jan Breman, Laureen Lammers, Tjitske Duiveman-de Boer, Willem van Eden, Paul Leufkens, and Femke Broere

Subjects

Medicine

Abstract

Introduction In rheumatoid arthritis (RA), immunosuppressive therapies may achieve symptomatic relief, but do not induce long-term, drug-free remission. Meanwhile, the lifelong use of immunosuppressive drugs confers increased risk for malignancy and infections. As such, there is an unmet need for novel treatments that selectively target the pathogenic immune response in RA by inducing tolerance to autoantigens. Autologous cell therapy using antigen-loaded tolerogenic dendritic cells (tolDCs) aims to reinstate autoantigen-specific immunological tolerance in RA and could potentially meet this need.Methods and analysis We report here the design of the phase I/II, investigator-initiated, open-label, dose-escalation trial TOLERANT. In this study, we will evaluate the intranodal administration of tolDCs in patients with RA that are in remission under immunosuppressive therapy. The tolDCs in this trial are loaded with the heat shock protein 70-derived peptide mB29a, which is an effective surrogate autoantigen in animal models of arthritis. Within this study, three dose-escalation cohorts (two intranodal injections of 5×106, 10×106 and 15×106 tolDCs), each consisting of three patients, are evaluated to identify the highest safe dose (recommended dose), and an extension cohort of nine patients will be treated with the recommended dose. The (co-)primary endpoints of this study are safety and feasibility, which we assess by the number of AEs and the successful production of tolDCs. The secondary endpoints include the immunological effects of the treatment, which we assess with a variety of high-dimensional and antigen-specific immunological assays. Clinical effects are exploratory outcomes.Ethics and dissemination Ethical approval for this study has been obtained from the Netherlands Central Committee on Research Involving Human Subjects. The outcomes of the trial will be disseminated through publications in open-access, peer-reviewed scientific journals, scientific conferences and to patient associations.Trial registration numbers NCT05251870; 2019-003620-20 (EudraCT); NL71296.000.20 (CCMO register).

Published

2024

2. Adjuvant dendritic cell therapy in stage IIIB/C melanoma: the MIND-DC randomized phase III trial

Author

Kalijn F. Bol, Gerty Schreibelt, Martine Bloemendal, Wouter W. van Willigen, Simone Hins-de Bree, Anna L. de Goede, Annemiek J. de Boer, Kevin J. H. Bos, Tjitske Duiveman-de Boer, Michel A. M. Olde Nordkamp, Tom G. M. van Oorschot, Carlijn J. Popelier, Jeanne M. Pots, Nicole M. Scharenborg, Mandy W. M. M. van de Rakt, Valeska de Ruiter, Wilmy S. van Meeteren, Michelle M. van Rossum, Sandra J. Croockewit, Bouke J. Koeneman, Jeroen H. A. Creemers, Inge M. N. Wortel, Caroline Angerer, Mareke Brüning, Katja Petry, Andrzej Dzionek, Astrid A. van der Veldt, Dirk J. van Grünhagen, Johanna E. M. Werner, Johannes J. Bonenkamp, John B. A. G. Haanen, Marye J. Boers-Sonderen, Rutger H. T. Koornstra, Martijn F. Boomsma, Erik H. J. Aarntzen, Martin Gotthardt, James Nagarajah, Theo J. M. de Witte, Carl G. Figdor, Johannes H. W. de Wilt, Johannes Textor, Jan Willem B. de Groot, Winald R. Gerritsen, and I. Jolanda M. de Vries

Subjects

Science

Abstract

Abstract Autologous natural dendritic cells (nDCs) treatment can induce tumor-specific immune responses and clinical responses in cancer patients. In this phase III clinical trial (NCT02993315), 148 patients with resected stage IIIB/C melanoma were randomized to adjuvant treatment with nDCs (n = 99) or placebo (n = 49). Active treatment consisted of intranodally injected autologous CD1c+ conventional and plasmacytoid DCs loaded with tumor antigens. The primary endpoint was the 2-year recurrence-free survival (RFS) rate, whereas the secondary endpoints included median RFS, 2-year and median overall survival, adverse event profile, and immunological response The 2-year RFS rate was 36.8% in the nDC treatment group and 46.9% in the control group (p = 0.31). Median RFS was 12.7 months vs 19.9 months, respectively (hazard ratio 1.25; 90% CI: 0.88−1.79; p = 0.29). Median overall survival was not reached in both treatment groups (hazard ratio 1.32; 90% CI: 0.73−2.38; p = 0.44). Grade 3−4 study-related adverse events occurred in 5% and 6% of patients. Functional antigen-specific T cell responses could be detected in 67.1% of patients tested in the nDC treatment group vs 3.8% of patients tested in the control group (p

Published

2024

3. Influence of microbiota-associated metabolic reprogramming on clinical outcome in patients with melanoma from the randomized adjuvant dendritic cell-based MIND-DC trial

Author

Carolina Alves Costa Silva, Gianmarco Piccinno, Déborah Suissa, Mélanie Bourgin, Gerty Schreibelt, Sylvère Durand, Roxanne Birebent, Marine Fidelle, Cissé Sow, Fanny Aprahamian, Paolo Manghi, Michal Punčochář, Francesco Asnicar, Federica Pinto, Federica Armanini, Safae Terrisse, Bertrand Routy, Damien Drubay, Alexander M. M. Eggermont, Guido Kroemer, Nicola Segata, Laurence Zitvogel, Lisa Derosa, Kalijn F. Bol, and I. Jolanda M. de Vries

Subjects

Science

Abstract

Abstract Tumor immunosurveillance plays a major role in melanoma, prompting the development of immunotherapy strategies. The gut microbiota composition, influencing peripheral and tumoral immune tonus, earned its credentials among predictors of survival in melanoma. The MIND-DC phase III trial (NCT02993315) randomized (2:1 ratio) 148 patients with stage IIIB/C melanoma to adjuvant treatment with autologous natural dendritic cell (nDC) or placebo (PL). Overall, 144 patients collected serum and stool samples before and after 2 bimonthly injections to perform metabolomics (MB) and metagenomics (MG) as prespecified exploratory analysis. Clinical outcomes are reported separately. Here we show that different microbes were associated with prognosis, with the health-related Faecalibacterium prausnitzii standing out as the main beneficial taxon for no recurrence at 2 years (p = 0.008 at baseline, nDC arm). Therapy coincided with major MB perturbations (acylcarnitines, carboxylic and fatty acids). Despite randomization, nDC arm exhibited MG and MB bias at baseline: relative under-representation of F. prausnitzii, and perturbations of primary biliary acids (BA). F. prausnitzii anticorrelated with BA, medium- and long-chain acylcarnitines. Combined, these MG and MB biomarkers markedly determined prognosis. Altogether, the host-microbial interaction may play a role in localized melanoma. We value systematic MG and MB profiling in randomized trials to avoid baseline differences attributed to host-microbe interactions.

Published

2024

4. Dendritic cell vaccination combined with carboplatin/paclitaxel for metastatic endometrial cancer patients: results of a phase I/II trial

Author

Bouke J. Koeneman, Gerty Schreibelt, Mark A. J. Gorris, Simone Hins - de Bree, Harm Westdorp, Petronella B. Ottevanger, and I. Jolanda M. de Vries

Subjects

endometrial cancer (EC), immunotherapy, chemoimmunotherapy, DC vaccination, dendritic cells, Immunologic diseases. Allergy, RC581-607

Abstract

BackgroundMetastatic endometrial cancer (mEC) continues to have a poor prognosis despite the introduction of several novel therapies including immune checkpoints inhibitors. Dendritic cell (DC) vaccination is known to be a safe immunotherapeutic modality that can induce immunological and clinical responses in patients with solid tumors. Platinum-based chemotherapy is known to act synergistically with immunotherapy by selectively depleting suppressive immune cells. Therefore, we investigated the immunological efficacy of combined chemoimmunotherapy with an autologous DC vaccine and carboplatin/paclitaxel chemotherapy.Study designThis is a prospective, exploratory, single-arm phase I/II study (NCT04212377) in 7 patients with mEC. The DC vaccine consisted of blood-derived conventional and plasmacytoid dendritic cells, loaded with known mEC antigens Mucin-1 and Survivin. Chemotherapy consisted of carboplatin/paclitaxel, given weekly for 6 cycles and three-weekly for 3 cycles. The primary endpoint was immunological vaccine efficacy; secondary endpoints were safety and feasibility.ResultsProduction of DC vaccines was successful in five out of seven patients. These five patients started study treatment and all were able to complete the entire treatment schedule. Antigen-specific responses could be demonstrated in two of the five patients who were treated. All patients had at least one adverse event grade 3 or higher. Treatment-related adverse events grade ≥3 were related to chemotherapy rather than DC vaccination; neutropenia was most common. Suppressive myeloid cells were selectively depleted in peripheral blood after chemotherapy.ConclusionDC vaccination can be safely combined with carboplatin/paclitaxel in patients with metastatic endometrial cancer and induces antigen-specific responses in a minority of patients. Longitudinal immunological phenotyping is suggestive of a synergistic effect of the combination.

Published

2024

5. Human Dendritic Cell Subset Isolation by Magnetic Bead Sorting: A Protocol to Efficiently Obtain Pure Populations

Author

Georgina Flórez-Grau, Jorge Cuenca Escalona, Helena Lacasta-Mambo, Daphne Roelofs, Johanna Bödder, Ruben Beuk, Gerty Schreibelt, and I Jolanda de Vries

Subjects

Biology (General), QH301-705.5

Abstract

Dendritic cells have been investigated for cell-based immunotherapy for various applications. The low abundance of dendritic cells in blood hampers their clinical application, resulting in the use of monocyte-derived dendritic cells as an alternative cell type. Limited knowledge is available regarding blood-circulating human dendritic cells, which can be divided into three subsets: type 2 conventional dendritic cells, type 1 conventional dendritic cells, and plasmacytoid dendritic cells. These subsets exhibit unique and desirable features for dendritic cell-based therapies. To enable efficient and reliable human research on dendritic cell subsets, we developed an efficient isolation protocol for the three human dendritic cell subsets, resulting in pure populations. The sequential steps include peripheral blood mononuclear cell isolation, magnetic-microbead lineage depletion (CD14, CD56, CD3, and CD19), and individual magnetic-microbead isolation of the three human dendritic cell subsets.Graphical overviewScheme of the dendritic cell (DC) isolation protocol. Starting material for this process is human blood (buffy coat or aphaeresis). From that, peripheral blood mononuclear cells (PBMCs) are isolated by using ficoll gradient centrifugation. Then, an enrichment for DCs is performed using semi-automated equipment. From the enriched fraction, DC subsets are obtained by magnetic cell sorting.

Published

2023

6. Trial watch: Dendritic cell (DC)-based immunotherapy for cancer

Author

Raquel S Laureano, Jenny Sprooten, Isaure Vanmeerbeerk, Daniel M Borras, Jannes Govaerts, Stefan Naulaerts, Zwi N Berneman, Benoit Beuselinck, Kalijn F Bol, Jannie Borst, an Coosemans, Angeliki Datsi, Jitka Fučíková, Lisa Kinget, Bart Neyns, Gerty Schreibelt, Evelien Smits, Rüdiger V Sorg, Radek Spisek, Kris Thielemans, Sandra Tuyaerts, Steven De Vleeschouwer, I Jolanda M de Vries, Yanling Xiao, and Abhishek D Garg

Subjects

Dendritic cells, DAMPs, TAAs, antigen cross-presentation, T cell priming, immune checkpoint blockers, Immunologic diseases. Allergy, RC581-607, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Dendritic cell (DC)-based vaccination for cancer treatment has seen considerable development over recent decades. However, this field is currently in a state of flux toward niche-applications, owing to recent paradigm-shifts in immuno-oncology mobilized by T cell-targeting immunotherapies. DC vaccines are typically generated using autologous (patient-derived) DCs exposed to tumor-associated or -specific antigens (TAAs or TSAs), in the presence of immunostimulatory molecules to induce DC maturation, followed by reinfusion into patients. Accordingly, DC vaccines can induce TAA/TSA-specific CD8+/CD4+ T cell responses. Yet, DC vaccination still shows suboptimal anti-tumor efficacy in the clinic. Extensive efforts are ongoing to improve the immunogenicity and efficacy of DC vaccines, often by employing combinatorial chemo-immunotherapy regimens. In this Trial Watch, we summarize the recent preclinical and clinical developments in this field and discuss the ongoing trends and future perspectives of DC-based immunotherapy for oncological indications.

Published

2022

7. Immunological responses to adjuvant vaccination with combined CD1c+ myeloid and plasmacytoid dendritic cells in stage III melanoma patients

Author

Martine Bloemendal, Kalijn F. Bol, Steve Boudewijns, Mark A.J. Gorris, Johannes H.W. de Wilt, Sandra A.J. Croockewit, Michelle M. van Rossum, Anna L. de Goede, Katja Petry, Rutger H.T. Koornstra, Carl Figdor, Winald R. Gerritsen, Gerty Schreibelt, and I. Jolanda M. de Vries

Subjects

melanoma, immunotherapy, clinical trial, Immunologic diseases. Allergy, RC581-607, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

We evaluated the immunological responses of lymph-node involved (stage III) melanoma patients to adjuvant dendritic cell vaccination with subsets of naturally occurring dendritic cells (nDCs). Fifteen patients with completely resected stage III melanoma were randomized to receive adjuvant dendritic cell vaccination with CD1c+ myeloid dendritic cells (cDC2s), plasmacytoid dendritic cells (pDCs) or the combination. Immunological response was the primary endpoint and secondary endpoints included safety and survival. In 80% of the patients, antigen-specific CD8+ T cells were detected in skin test-derived T cells and in 55% of patients, antigen-specific CD8+ T cells were detectable in peripheral blood. Functional interferon-γ-producing T cells were found in the skin test of 64% of the patients. Production of nDC vaccines meeting release criteria was feasible for all patients. Vaccination only induced grade 1–2 adverse events, mainly consisting of fatigue. In conclusion, adjuvant dendritic cell vaccination with cDC2s and/or pDCs is feasible, safe and induced immunological responses in the majority of stage III melanoma patients.

Published

2022

8. Blood-derived dendritic cell vaccinations induce immune responses that correlate with clinical outcome in patients with chemo-naive castration-resistant prostate cancer

Author

Harm Westdorp, Jeroen H. A. Creemers, Inge M. van Oort, Gerty Schreibelt, Mark A. J. Gorris, Niven Mehra, Michiel Simons, Anna L. de Goede, Michelle M. van Rossum, Alexandra J. Croockewit, Carl G. Figdor, J. Alfred Witjes, Erik H. J. G. Aarntzen, Roel D. M. Mus, Mareke Brüning, Katja Petry, Martin Gotthardt, Jelle O. Barentsz, I. Jolanda M. de Vries, and Winald R. Gerritsen

Subjects

Castration-resistant prostate cancer, Dendritic cell vaccination, Immunotherapy, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Clinical benefit of cellular immunotherapy has been shown in patients with castration-resistant prostate cancer (CRPC). We investigated the immunological response and clinical outcome of vaccination with blood-derived CD1c+ myeloid dendritic cells (mDCs; cDC2) and plasmacytoid DCs (pDCs). Methods In this randomized phase IIa trial, 21 chemo-naive CRPC patients received maximally 9 vaccinations with mature mDCs, pDCs or a combination of mDCs plus pDCs. DCs were stimulated with protamine/mRNA and loaded with tumor-associated antigens NY-ESO-1, MAGE-C2 and MUC1. Primary endpoint was the immunological response after DC vaccination, which was monitored in peripheral blood and in T cell cultures of biopsies of post-treatment delayed-type hypersensitivity-skin tests. Main secondary endpoints were safety, feasibility, radiological PFS (rPFS) and overall survival. Radiological responses were assessed by MRIs and contrast-enhanced 68Ga-prostate-specific membrane antigen PET/CT, according to RECIST 1.1, PCWG2 criteria and immune-related response criteria. Results Both tetramer/dextramer-positive (dm+) and IFN-γ-producing (IFN-γ+) antigen specific T cells were detected more frequently in skin biopsies of patients with radiological non-progressive disease (5/13 patients; 38%) compared to patients with progressive disease (0/8 patients; 0%). In these patients with vaccination enhanced dm+ and IFN-γ+ antigen-specific T cells median rPFS was 18.8 months (n = 5) vs. 5.1 months (n = 16) in patients without IFN-γ-producing antigen-specific T cells (p = 0.02). The overall median rPFS was 9.5 months. All DC vaccines were well tolerated with grade 1–2 toxicity. Conclusions Immunotherapy with blood-derived DC subsets was feasible and safe and induced functional antigen-specific T cells. The presence of functional antigen-specific T cells correlated with an improved clinical outcome. Trial registration ClinicalTrials.gov identifier NCT02692976, registered 26 February 2016, retrospectively registered.

Published

2019

9. The clinical application of cancer immunotherapy based on naturally circulating dendritic cells

Author

Kalijn F. Bol, Gerty Schreibelt, Katrin Rabold, Stefanie K. Wculek, Julia Katharina Schwarze, Andrzej Dzionek, Alvaro Teijeira, Lana E. Kandalaft, Pedro Romero, George Coukos, Bart Neyns, David Sancho, Ignacio Melero, and I. Jolanda M. de Vries

Subjects

Dendritic cells, Natural dendritic cells, Plasmacytoid dendritic cells, Myeloid dendritic cells, Conventional dendritic cells, Cross-presenting dendritic cells, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Dendritic cells (DCs) can initiate and direct adaptive immune responses. This ability is exploitable in DC vaccination strategies, in which DCs are educated ex vivo to present tumor antigens and are administered into the patient with the aim to induce a tumor-specific immune response. DC vaccination remains a promising approach with the potential to further improve cancer immunotherapy with little or no evidence of treatment-limiting toxicity. However, evidence for objective clinical antitumor activity of DC vaccination is currently limited, hampering the clinical implementation. One possible explanation for this is that the most commonly used monocyte-derived DCs may not be the best source for DC-based immunotherapy. The novel approach to use naturally circulating DCs may be an attractive alternative. In contrast to monocyte-derived DCs, naturally circulating DCs are relatively scarce but do not require extensive culture periods. Thereby, their functional capabilities are preserved, the reproducibility of clinical applications is increased, and the cells are not dysfunctional before injection. In human blood, at least three DC subsets can be distinguished, plasmacytoid DCs, CD141+ and CD1c+ myeloid/conventional DCs, each with distinct functional characteristics. In completed clinical trials, either CD1c+ myeloid DCs or plasmacytoid DCs were administered and showed encouraging immunological and clinical outcomes. Currently, also the combination of CD1c+ myeloid and plasmacytoid DCs as well as the intratumoral use of CD1c+ myeloid DCs is under investigation in the clinic. Isolation and culture strategies for CD141+ myeloid DCs are being developed. Here, we summarize and discuss recent clinical developments and future prospects of natural DC-based immunotherapy.

Published

2019

10. PTEN Hamartoma Tumor Syndrome and Immune Dysregulation

Author

Marc Eissing, Lise Ripken, Gerty Schreibelt, Harm Westdorp, Marjolijn Ligtenberg, Romana Netea-Maier, Mihai G. Netea, I. Jolanda M. de Vries, and Nicoline Hoogerbrugge

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Carriers of a pathogenic germline mutations in the PTEN gene, a well-known tumor suppressor gene, are at increased risk of multiple benign and malignant tumors, e.g. breast, thyroid, endometrial and colon cancer. This is called PTEN Hamartomous Tumor Syndrome (PHTS). PHTS patients may also have an increased risk of immunological dysregulation, such as autoimmunity and immune deficiencies. The effects of PTEN on the immune system have been studied in murine knockout models demonstrating that loss of PTEN function leads to dysregulation of the immune response. This results in susceptibility to autoimmunity, impaired B cell class switching with subsequent hypogammaglobulinemia. Additionally, a decreased ability of dendritic cells to prime CD8+ T cells was observed, leading to impaired tumor eradication. Immune dysfunction in PHTS patients has not yet been extensively studied but might be a manageable contributing factor to the increased cancer risk in PHTS.

Published

2019

11. Harnessing the cDC1-NK Cross-Talk in the Tumor Microenvironment to Battle Cancer

Author

Johanna Bödder, Tasmin Zahan, Rianne van Slooten, Gerty Schreibelt, I. Jolanda M. de Vries, and Georgina Flórez-Grau

Subjects

natural killer cells, conventional type 1 DCs, cross-talk, tumor microenvironment, immunotherapy, Immunologic diseases. Allergy, RC581-607

Abstract

Immunotherapeutic approaches have revolutionized the treatment of several diseases such as cancer. The main goal of immunotherapy for cancer is to modulate the anti-tumor immune responses by favoring the recognition and destruction of tumor cells. Recently, a better understanding of the suppressive effect of the tumor microenvironment (TME) on immune cells, indicates that restoring the suppressive effect of the TME is crucial for an efficient immunotherapy. Natural killer (NK) cells and dendritic cells (DCs) are cell types that are currently administered to cancer patients. NK cells are used because of their ability to kill tumor cells directly via cytotoxic granzymes. DCs are employed to enhance anti-tumor T cell responses based on their ability to present antigens and induce tumor-antigen specific CD8+ T cell responses. In preclinical models, a particular DC subset, conventional type 1 DCs (cDC1s) is shown to be specialized in cross-presenting extracellular antigens to CD8+ T cells. This feature makes them a promising DC subset for cancer treatment. Within the TME, cDC1s show a bidirectional cross-talk with NK cells, resulting in a higher cDC1 recruitment, differentiation, and maturation as well as activation and stimulation of NK cells. Consequently, the presence of cDC1s and NK cells within the TME might be of utmost importance for the success of immunotherapy. In this review, we discuss the function of cDC1s and NK cells, their bidirectional cross-talk and potential strategies that could improve cancer immunotherapy.

Published

2021

12. High Health-Related Quality of Life During Dendritic Cell Vaccination Therapy in Patients With Castration-Resistant Prostate Cancer

Author

Harm Westdorp, Jeroen H. A. Creemers, Inge M. van Oort, Niven Mehra, Simone M. Hins-de Bree, Carl G. Figdor, J. Alfred Witjes, Gerty Schreibelt, I. Jolanda M. de Vries, Winald R. Gerritsen, and Petronella B. Ottevanger

Subjects

health-related quality of life (HRQoL), patient-reported outcomes (PROs), dendritic cell vaccination, immunotherapy, castration-resistant prostate cancer, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

BackgroundMaintaining health-related quality of life (HRQoL) is highly desirable during systemic therapies for patients with castration-resistant prostate cancer (CRPC). Patient-reported outcome measures (PROs) were studied in our phase IIa trial on cellular-based immunotherapy with dendritic cells (DC).MethodsWe treated 21 chemo-naive asymptomatic or minimally symptomatic patients with CRPC with maximally three cycles of DC vaccinations (ClinicalTrials.gov, NCT02692976). Here, we report the impact of DC vaccination on HRQoL. PROs were assessed using the EORTC-QLQ-C30, the EORTC-QLQ-PR25, Checklist Individual Strength (CIS20-R), and Beck Depression Inventory Primary Care questionnaires. Short-term and long-term vaccine-related effects on HRQoL were studied.ResultsQuestionnaires were collected at baseline (n=20), week 6 (n=19), week 12 (n=18), week 24 (n=13), week 50 (n=8) and week 100 (n=2). No clinically relevant differences in symptom-related outcome, functioning-related outcome, and Global Health Status were observed directly after the first cycle of DC vaccinations (week 6) and at follow-up (week 12) compared to baseline. HRQoL remained high throughout the vaccination cycle and six weeks afterward. In radiographic non-progressive patients, who continued DC vaccination, high HRQoL scores were observed up to one and two years after study enrolment.ConclusionsPatients with asymptomatic or minimally symptomatic CRPC show high HRQoL throughout DC-based immunotherapy. This is a clinically relevant finding in this older-aged patient population with advanced prostate cancer.

Published

2020

13. Response and survival of metastatic melanoma patients treated with immune checkpoint inhibition for recurrent disease on adjuvant dendritic cell vaccination

Author

Wouter W. van Willigen, Martine Bloemendal, Marye J. Boers-Sonderen, Jan Willem B. de Groot, Rutger H.T. Koornstra, Astrid A.M. van der Veldt, John B. A. G. Haanen, Steve Boudewijns, Gerty Schreibelt, Winald R. Gerritsen, I. Jolanda M. de Vries, and Kalijn F. Bol

Subjects

melanoma, immunotherapy, adjuvant, dendritic cell, vaccination, Immunologic diseases. Allergy, RC581-607, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Vaccination with autologous dendritic cells (DC) loaded ex vivo with melanoma-associated antigens is currently being tested as an adjuvant treatment modality for resected locoregional metastatic (stage III) melanoma. Based on its mechanism of action, DC vaccination might potentiate the clinical efficacy of concurrent or sequential immune checkpoint inhibition (ICI). The purpose of this study was to determine the efficacy of ICI administered following recurrent disease during, or after, adjuvant DC vaccination. To this end, we retrospectively analyzed clinical responses of 51 melanoma patients with either irresectable stage III or stage IV disease treated with first- or second-line ICI following recurrence on adjuvant DC vaccination. Patients were analyzed according to the form of ICI administered: PD-1 inhibition monotherapy (nivolumab or pembrolizumab), ipilimumab monotherapy or combined treatment with ipilimumab and nivolumab. Treatment with first- or second-line PD-1 inhibition monotherapy after recurrence on adjuvant DC vaccination resulted in a response rate of 52%. In patients treated with ipilimumab monotherapy and ipilimumab-nivolumab response rates were 35% and 75%, respectively. In conclusion, ICI is effective in melanoma patients with recurrent disease on adjuvant DC vaccination.

Published

2020

14. Human pDCs Are Superior to cDC2s in Attracting Cytolytic Lymphocytes in Melanoma Patients Receiving DC Vaccination

Author

Jasper J.P. van Beek, Georgina Flórez-Grau, Mark A.J. Gorris, Till S.M. Mathan, Gerty Schreibelt, Kalijn F. Bol, Johannes Textor, and I. Jolanda M. de Vries

Subjects

Biology (General), QH301-705.5

Abstract

Summary: Plasmacytoid dendritic cells (pDCs) and type 2 conventional dendritic cells (cDC2s) are currently under evaluation for use in cancer vaccines. Although both DC subsets can activate adaptive and innate lymphocytes, their capacity to recruit such cells is rarely considered. Here, we show that pDCs and cDC2s display a striking difference in chemokine secretion, which correlates with the recruitment of distinct types of immune effector cells. Activated pDCs express high levels of CXCR3 ligands and attract more CD8+ T cells, CD56+ T cells, and γδ T cells in vitro, compared to cDC2s. Skin from melanoma patients shows an influx of immune effector cells following intradermal vaccination with pDCs or cDC2s, with pDCs inducing the strongest influx of lymphocytes known to possess cytolytic activity. These findings suggest that combining both DC subsets could unite the preferred chemoattractive properties of pDCs with the superior T cell priming properties of cDC2s to ultimately enhance vaccine efficacy. : Human plasmacytoid dendritic cells and type 2 conventional dendritic cells are currently used in cancer vaccines to induce antitumor immune responses. van Beek et al. compared their chemoattractive properties and identified a striking difference in chemokine secretion, resulting in the attraction of distinct immune effector cells. Keywords: pDC, cDC2, chemokines, migration, DC vaccines

Published

2020

15. Challenges of Neoantigen Targeting in Lynch Syndrome and Constitutional Mismatch Repair Deficiency Syndrome

Author

Asima Abidi, Mark A. J. Gorris, Evan Brennan, Marjolijn C. J. Jongmans, Dilys D. Weijers, Roland P. Kuiper, Richarda M. de Voer, Nicoline Hoogerbrugge, Gerty Schreibelt, and I. Jolanda M. de Vries

Subjects

Lynch Syndrome, hereditary cancer, CMMRD, neoantigen, colorectal cancer, mismatch repair deficiency, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Lynch syndrome (LS) and constitutional mismatch repair deficiency (CMMRD) are hereditary disorders characterised by a highly increased risk of cancer development. This is due to germline aberrations in the mismatch repair (MMR) genes, which results in a high mutational load in tumours of these patients, including insertions and deletions in genes bearing microsatellites. This generates microsatellite instability and cause reading frameshifts in coding regions that could lead to the generation of neoantigens and opens up avenues for neoantigen targeting immune therapies prophylactically and therapeutically. However, major obstacles need to be overcome, such as the heterogeneity in tumour formation within and between LS and CMMRD patients, which results in considerable variability in the genes targeted by mutations, hence challenging the choice of suitable neoantigens. The machine-learning methods such as NetMHC and MHCflurry that predict neoantigen- human leukocyte antigen (HLA) binding affinity provide little information on other aspects of neoantigen presentation. Immune escape mechanisms that allow MMR-deficient cells to evade surveillance combined with the resistance to immune checkpoint therapy make the neoantigen targeting regimen challenging. Studies to delineate shared neoantigen profiles across patient cohorts, precise HLA binding algorithms, additional therapies to counter immune evasion and evaluation of biomarkers that predict the response of these patients to immune checkpoint therapy are warranted.

Published

2021

16. Dendritic Cell Cancer Therapy: Vaccinating the Right Patient at the Right Time

Author

Wouter W. van Willigen, Martine Bloemendal, Winald R. Gerritsen, Gerty Schreibelt, I. Jolanda M. de Vries, and Kalijn F. Bol

Subjects

dendritic cell, vaccination, immunotherapy, checkpoint inhibitor, cancer, adjuvant, Immunologic diseases. Allergy, RC581-607

Abstract

Immune checkpoint inhibitors propelled the field of oncology with clinical responses in many different tumor types. Superior overall survival over chemotherapy has been reported in various metastatic cancers. Furthermore, prolonged disease-free and overall survival have been reported in the adjuvant treatment of stage III melanoma. Unfortunately, a substantial portion of patients do not obtain a durable response. Therefore, additional strategies for the treatment of cancer are still warranted. One of the numerous options is dendritic cell vaccination, which employs the central role of dendritic cells in activating the innate and adaptive immune system. Over the years, dendritic cell vaccination was shown to be able to induce an immunologic response, to increase the number of tumor infiltrating lymphocytes and to provide overall survival benefit for at least a selection of patients in phase II studies. However, with the success of immune checkpoint inhibition in several malignancies and considering the plethora of other treatment modalities being developed, it is of utmost importance to delineate the position of dendritic cell therapy in the treatment landscape of cancer. In this review, we address some key questions regarding the integration of dendritic cell vaccination in future cancer treatment paradigms.

Published

2018

17. Proteomics of Human Dendritic Cell Subsets Reveals Subset-Specific Surface Markers and Differential Inflammasome Function

Author

Kuntal Worah, Till S.M. Mathan, Thien Phong Vu Manh, Shivakumar Keerthikumar, Gerty Schreibelt, Jurjen Tel, Tjitske Duiveman-de Boer, Annette E. Sköld, Annemiek B. van Spriel, I. Jolanda M. de Vries, Martijn A. Huynen, Hans J. Wessels, Jolein Gloerich, Marc Dalod, Edwin Lasonder, Carl G. Figdor, and Sonja I. Buschow

Subjects

Biology (General), QH301-705.5

Abstract

Dendritic cells (DCs) play a key role in orchestrating adaptive immune responses. In human blood, three distinct subsets exist: plasmacytoid DCs (pDCs) and BDCA3+ and CD1c+ myeloid DCs. In addition, a DC-like CD16+ monocyte has been reported. Although RNA-expression profiles have been previously compared, protein expression data may provide a different picture. Here, we exploited label-free quantitative mass spectrometry to compare and identify differences in primary human DC subset proteins. Moreover, we integrated these proteomic data with existing mRNA data to derive robust cell-specific expression signatures with more than 400 differentially expressed proteins between subsets, forming a solid basis for investigation of subset-specific functions. We illustrated this by extracting subset identification markers and by demonstrating that pDCs lack caspase-1 and only express low levels of other inflammasome-related proteins. In accordance, pDCs were incapable of interleukin (IL)-1β secretion in response to ATP.

Published

2016

18. Primary Human Blood Dendritic Cells for Cancer Immunotherapy—Tailoring the Immune Response by Dendritic Cell Maturation

Author

Simone P. Sittig, I. Jolanda M. de Vries, and Gerty Schreibelt

Subjects

human blood DC (dendritic cell) subsets, maturation, DC-based cancer vaccines, plasmacytoid DC, myeloid DC, CD141+ myeloid DC (mDC), CD1c+ mDC, Biology (General), QH301-705.5

Abstract

Dendritic cell (DC)-based cancer vaccines hold the great promise of tipping the balance from tolerance of the tumor to rejection. In the last two decades, we have gained tremendous knowledge about DC-based cancer vaccines. The maturation of DCs has proven indispensable to induce immunogenic T cell responses. We review the insights gained from the development of maturation cocktails in monocyte derived DC-based trials. More recently, we have also gained insights into the functional specialization of primary human blood DC subsets. In peripheral human blood, we can distinguish at least three primary DC subsets, namely CD1c+ and CD141+ myeloid DCs and plasmacytoid DCs. We reflect the current knowledge on maturation and T helper polarization by these blood DC subsets in the context of DC-based cancer vaccines. The maturation stimulus in combination with the DC subset will determine the type of T cell response that is induced. First trials with these natural DCs underline their excellent in vivo functioning and mark them as promising tools for future vaccination strategies.

Published

2015

19. Immune Curbing of Cancer Stem Cells by CTLs Directed to NANOG

Author

Christina Wefers, Gerty Schreibelt, Leon F. A. G. Massuger, I. Jolanda M. de Vries, and Ruurd Torensma

Subjects

dendritic cell vaccination, cancer stem cells, MHC class I, NANOG, cancer stem cell immunity, Immunologic diseases. Allergy, RC581-607

Abstract

Cancer stem cells (CSCs) have been identified as the source of tumor growth and disease recurrence. Eradication of CSCs is thus essential to achieve durable responses, but CSCs are resistant to current anti-tumor therapies. Novel therapeutic approaches that specifically target CSCs will, therefore, be crucial to improve patient outcome. Immunotherapies, which boost the body’s own immune system to eliminate cancerous cells, could be an alternative approach to target CSCs. Vaccines of dendritic cells (DCs) loaded with tumor antigens can evoke highly specific anti-tumor T cell responses. Importantly, DC vaccination also promotes immunological memory formation, paving the way for long-term cancer control. Here, we propose a DC vaccination that specifically targets CSCs. DCs loaded with NANOG peptides, a protein required for maintaining stem cell properties, could evoke a potent anti-tumor immune response against CSCs. We hypothesize that the resulting immunological memory will also control newly formed CSCs, thereby preventing disease recurrence.

Published

2018

20. A Comparative Study of the T Cell Stimulatory and Polarizing Capacity of Human Primary Blood Dendritic Cell Subsets

Author

Simone P. Sittig, Ghaith Bakdash, Jorieke Weiden, Annette E. Sköld, Jurjen Tel, Carl G. Figdor, I. Jolanda M. de Vries, and Gerty Schreibelt

Subjects

Pathology, RB1-214

Abstract

Dendritic cells (DCs) are central players of immune responses; they become activated upon infection or inflammation and migrate to lymph nodes, where they can initiate an antigen-specific immune response by activating naive T cells. Two major types of naturally occurring DCs circulate in peripheral blood, namely, myeloid and plasmacytoid DCs (pDCs). Myeloid DCs (mDCs) can be subdivided based on the expression of either CD1c or CD141. These human DC subsets differ in surface marker expression, Toll-like receptor (TLR) repertoire, and transcriptional profile, suggesting functional differences between them. Here, we directly compared the capacity of human blood mDCs and pDCs to activate and polarize CD4+ T cells. CD141+ mDCs show an overall more mature phenotype over CD1c+ mDC and pDCs; they produce less IL-10 and more IL-12 than CD1c+ mDCs. Despite these differences, all subsets can induce the production of IFN-γ in naive CD4+ T cells. CD1c+ and CD141+ mDCs especially induce a strong T helper 1 profile. Importantly, naive CD4+ T cells are not polarized towards regulatory T cells by any subset. These findings further establish all three human blood DCs—despite their differences—as promising candidates for immunostimulatory effectors in cancer immunotherapy.

Published

2016

21. BDCA1+CD14+ Immunosuppressive Cells in Cancer, a Potential Target?

Author

Thomas J. van Ee, Heleen H. Van Acker, Tom G. van Oorschot, Viggo F. Van Tendeloo, Evelien L. Smits, Ghaith Bakdash, Gerty Schreibelt, and I. Jolanda M. de Vries

Subjects

BDCA1+CD14+ cells, cancer, dendritic cells, cancer immunotherapy, immune suppression, tumor microenvironment, Medicine

Abstract

Dendritic cell (DC) vaccines show promising effects in cancer immunotherapy. However, their efficacy is affected by a number of factors, including (1) the quality of the DC vaccine and (2) tumor immune evasion. The recently characterized BDCA1+CD14+ immunosuppressive cells combine both aspects; their presence in DC vaccines may directly hamper vaccine efficacy, whereas, in patients, BDCA1+CD14+ cells may suppress the induced immune response in an antigen-specific manner systemically and at the tumor site. We hypothesize that BDCA1+CD14+ cells are present in a broad spectrum of cancers and demand further investigation to reveal treatment opportunities and/or improvement for DC vaccines. In this review, we summarize the findings on BDCA1+CD14+ cells in solid cancers. In addition, we evaluate the presence of BDCA1+CD14+ cells in leukemic cancers. Preliminary results suggest that the presence of BDCA1+CD14+ cells correlates with clinical features of acute and chronic myeloid leukemia. Future research focusing on the differentiation from monocytes towards BDCA1+CD14+ cells could reveal more about their cell biology and clinical significance. Targeting these cells in cancer patients may improve the outcome of cancer immunotherapy.

Published

2018

22. Enterovirus-infected β-cells induce distinct response patterns in BDCA1+ and BDCA3+ human dendritic cells.

Author

Barbara M Schulte, Paul R Gielen, Esther D Kers-Rebel, Gerty Schreibelt, Frank J M van Kuppeveld, and Gosse J Adema

Subjects

Medicine, Science

Abstract

Enteroviruses often cause mild disease, yet are also linked to development of autoimmune diabetes. Dendritic cells (DCs) shape both innate and adaptive immune responses, including anti-viral responses. How different human DC subsets shape anti-viral responses, whether they have complementary or overlapping functions and how this relates to autoimmune responses is largely unknown. We used enterovirus-infected β-cells and freshly isolated human myeloid DC (mDC) subsets as a model for autoimmune type 1 diabetes. Our data show that both the BDCA1+ and BDCA3+ mDC subsets engulf mock- as well as virus-infected β-cells, albeit BDCA1+ mDCs are more efficient. Uptake of enterovirus-infected, but not mock-infected cells, activated both DC subsets as indicated by the induction of co-stimulatory molecules and secretion of type I and type III interferons. Both subsets produced similar amounts of interferon-α, yet the BDCA3+ DC were superior in IFN-λ production. The BDCA1+ mDCs more strongly upregulated PD-L1, and were superior in IL-12 and IL-10 production as compared to the BDCA3+ DC. Despite lack of IL-12 production by the BDCA3+ DC, both BDCA1+ and BDCA3+ DCs activated T cells in allogeneic mixed lymphocyte reaction towards a Th1-type reactivity while suppressing Th2-associated cytokines.

Published

2015

23. Supplementary Figure 1 from Route of Administration Modulates the Induction of Dendritic Cell Vaccine–Induced Antigen-Specific T Cells in Advanced Melanoma Patients

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, Sophie Lucas, Otto C. Boerman, Wim J.G. Oyen, Roel Mus, Michelle M. van Rossum, Sandra Croockewit, Annemiek J. de Boer, Mandy W.M.M. van de Rakt, Nicole M. Scharenborg, Joannes F.M. Jacobs, Erik H.J.G. Aarntzen, Annechien J.A. Lambeck, Gerty Schreibelt, I. Jolanda M. de Vries, and W. Joost Lesterhuis

Abstract

PDF file - 41K, Clinical protocol and immunization schedule.

Published

2023

24. Supplementary Figure 3 from Vaccination with mRNA-Electroporated Dendritic Cells Induces Robust Tumor Antigen-Specific CD4+ and CD8+ T Cells Responses in Stage III and IV Melanoma Patients

Author

Gosse J. Adema, Cornelis J. A. Punt, Carl G. Figdor, I. Jolanda M. de Vries, Kris Thielemans, Roel Mus, Danita H. Schuurhuis, Tjitske Duiveman-de Boer, Joannes F. M. Jacobs, Willeke A. M. Blokx, Michelle M. van Rossum, Johannes H. W. de Wilt, Alexandra J. Croockewit, W. Joost Lesterhuis, Kalijn Bol, Gerty Schreibelt, and Erik H. J. G. Aarntzen

Abstract

PDF file, 96K, Detection of tumor-specific T cells in SKIL cultures does not require challenge with defined epitopes. Tetramer analysis of SKILs cultured from biopsies of DTH reactions to DCs pulsed with tumor peptides (upper plots) or DCs electroporated with mRNA encoding tumor proteins (lower plots) of patients II-E-09 (A), II-E-03 (B), and II-E-10 (C). This figure shows that sampling DTH biopsy cultures with tetramers yields similar results when the patient is challenged with intradermal injections with DC pulsed with defined epitopes or DC electroporated with mRNA encoding the full tumor antigen.

Published

2023

25. Data from Vaccination with mRNA-Electroporated Dendritic Cells Induces Robust Tumor Antigen-Specific CD4+ and CD8+ T Cells Responses in Stage III and IV Melanoma Patients

Author

Gosse J. Adema, Cornelis J. A. Punt, Carl G. Figdor, I. Jolanda M. de Vries, Kris Thielemans, Roel Mus, Danita H. Schuurhuis, Tjitske Duiveman-de Boer, Joannes F. M. Jacobs, Willeke A. M. Blokx, Michelle M. van Rossum, Johannes H. W. de Wilt, Alexandra J. Croockewit, W. Joost Lesterhuis, Kalijn Bol, Gerty Schreibelt, and Erik H. J. G. Aarntzen

Abstract

Purpose: Electroporation of dendritic cells (DC) with mRNA encoding tumor-associated antigens (TAA) has multiple advantages compared to peptide loading. We investigated the immunologic and clinical responses to vaccination with mRNA-electroporated DC in stage III and IV melanoma patients.Experimental design: Twenty-six stage III HLA*02:01 melanoma patients scheduled for radical lymph node dissection (stage III) and 19 melanoma patients with irresectable locoregional or distant metastatic disease (referred to as stage IV) were included. Monocyte-derived DC, electroporated with mRNA encoding gp100 and tyrosinase, were pulsed with keyhole limpet hemocyanin and administered intranodally. TAA-specific T-cell responses were monitored in blood and skin-test infiltrating lymphocyte (SKIL) cultures.Results: Comparable numbers of vaccine-induced CD8+ and/or CD4+ TAA-specific T-cell responses were detected in SKIL cultures; 17/26 stage III patients and 11/19 stage IV patients. Strikingly, in this population, TAA-specific CD8+ T cells that recognize multiple epitopes and produce elevated levels of IFNγ upon antigenic challenge in vitro, were significantly more often observed in stage III patients; 15/17 versus 3/11 stage IV patients, P = 0.0033. In stage IV patients, one mixed and one partial response were documented. The presence or absence of IFNγ-producing TAA-specific CD8+ T cells in stage IV patients was associated with marked difference in median overall survival of 24.1 months versus 11.0 months, respectively.Conclusion: Vaccination with mRNA-electroporated DC induces a broad repertoire of IFNγ producing TAA-specific CD8+ and CD4+ T-cell responses, particularly in stage III melanoma patients. Clin Cancer Res; 18(19); 5460–70. ©2012 AACR.

Published

2023

26. Supplementary Figure 2 from Route of Administration Modulates the Induction of Dendritic Cell Vaccine–Induced Antigen-Specific T Cells in Advanced Melanoma Patients

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, Sophie Lucas, Otto C. Boerman, Wim J.G. Oyen, Roel Mus, Michelle M. van Rossum, Sandra Croockewit, Annemiek J. de Boer, Mandy W.M.M. van de Rakt, Nicole M. Scharenborg, Joannes F.M. Jacobs, Erik H.J.G. Aarntzen, Annechien J.A. Lambeck, Gerty Schreibelt, I. Jolanda M. de Vries, and W. Joost Lesterhuis

Abstract

PDF file - 55K, Consort flow chart.

Published

2023

27. Supplementary Figure 3 from Effective Clinical Responses in Metastatic Melanoma Patients after Vaccination with Primary Myeloid Dendritic Cells

Author

I. Jolanda M. de Vries, Carl G. Figdor, Cornelis J.A. Punt, Winald R. Gerritsen, Christian U. Blank, Sander Kelderman, Joannes F.M. Jacobs, Rutger H.T. Koornstra, Sandra A.J. Croockewit, Roel D.M. Mus, Marieke E.B. Welzen, Michelle M. van Rossum, Willeke A.M. Blokx, Katja Petry, Gregor Winkels, Jurjen Tel, Tom G.M. van Oorschot, Michel A.M. Olde Nordkamp, Jeanette M. Pots, Annemiek J. de Boer, Nicole M. Scharenborg, Mandy W.M.M. van de Rakt, Tjitske Duiveman-de Boer, Erik H.J.G. Aarntzen, Florian Wimmers, Harm Westdorp, Kalijn F. Bol, and Gerty Schreibelt

Abstract

Supplementary Figure 3. KLH-specific immune responses before and after DC vaccination. (A) KLH-specific T cell proliferation was analyzed before the first vaccination and after each DC vaccination during the first vaccination cycle in peripheral blood of vaccinated metastatic melanoma patients. Per time point each dot represents 1 patient. Proliferative response to KLH is given as proliferation index (proliferation with KLH/proliferation without KLH). The two patients not showing a KLH-specific T cell response are shown in grey. (B) KLH-specific IgG, IgA, and IgM antibodies were quantitatively measured after each vaccination cycle in sera of vaccinated patients. Per isotype each dot represents one patient. Best KLH responses per patient are shown.

Published

2023

28. Supplementary Table 1 from Targeting of 111In-Labeled Dendritic Cell Human Vaccines Improved by Reducing Number of Cells

Author

I. Jolanda M. de Vries, Wim J. Oyen, Carl G. Figdor, Arend Heerschap, Gosse J. Adema, Cornelius J.A. Punt, Maichel van Riel, W. Joost Lesterhuis, Mandy van de Rakt, Gerty Schreibelt, Pauline Verdijk, Luis J. Cruz, Fernando Bonetto, Mangala Srinivas, and Erik H.J.G. Aarntzen

Abstract

PDF file - 62K, This table describes patient details, including disease state and prior treatments.

Published

2023

29. Supplementary Figure 1 from Vaccination with mRNA-Electroporated Dendritic Cells Induces Robust Tumor Antigen-Specific CD4+ and CD8+ T Cells Responses in Stage III and IV Melanoma Patients

Author

Gosse J. Adema, Cornelis J. A. Punt, Carl G. Figdor, I. Jolanda M. de Vries, Kris Thielemans, Roel Mus, Danita H. Schuurhuis, Tjitske Duiveman-de Boer, Joannes F. M. Jacobs, Willeke A. M. Blokx, Michelle M. van Rossum, Johannes H. W. de Wilt, Alexandra J. Croockewit, W. Joost Lesterhuis, Kalijn Bol, Gerty Schreibelt, and Erik H. J. G. Aarntzen

Abstract

PDF file, 149K, CONSORT flow chart.

Published

2023

30. Data from Route of Administration Modulates the Induction of Dendritic Cell Vaccine–Induced Antigen-Specific T Cells in Advanced Melanoma Patients

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, Sophie Lucas, Otto C. Boerman, Wim J.G. Oyen, Roel Mus, Michelle M. van Rossum, Sandra Croockewit, Annemiek J. de Boer, Mandy W.M.M. van de Rakt, Nicole M. Scharenborg, Joannes F.M. Jacobs, Erik H.J.G. Aarntzen, Annechien J.A. Lambeck, Gerty Schreibelt, I. Jolanda M. de Vries, and W. Joost Lesterhuis

Abstract

Purpose: It is unknown whether the route of administration influences dendritic cell (DC)-based immunotherapy. We compared the effect of intradermal versus intranodal administration of a DC vaccine on induction of immunologic responses in melanoma patients and examined whether concomitant administration of interleukin (IL)-2 increases the efficacy of the DC vaccine.Experimental Design: HLA-A2.1+ melanoma patients scheduled for regional lymph node dissection were vaccinated four times biweekly via intradermal or intranodal injection with 12 × 106 to 17 × 106 mature DCs loaded with tyrosinase and gp100 peptides together with keyhole limpet hemocyanin (KLH). Half of the patients also received low-dose IL-2 (9 MIU daily for 7 days starting 3 days after each vaccination). KLH-specific B- and T-cell responses were monitored in blood. gp100- and tyrosinase-specific T-cell responses were monitored in blood by tetramer analysis and in biopsies from delayed-type hypersensitivity (DTH) skin tests by tetramer and functional analyses with 51Cr release assays or IFNγ release, following coculture with peptide-pulsed T2 cells or gp100- or tyrosinase-expressing tumor cells.Results: In 19 of 43 vaccinated patients, functional tumor antigen–specific T cells could be detected. Although significantly more DCs migrated to adjacent lymph nodes upon intranodal vaccination, this was also highly variable with a complete absence of migration in 7 of 24 intranodally vaccinated patients. Intradermal vaccinations proved superior in inducing functional tumor antigen–specific T cells. Coadministration of IL-2 did not further augment the antigen-specific T-cell response but did result in higher regulatory T-cell frequencies.Conclusion: Intradermal vaccination resulted in superior antitumor T-cell induction when compared with intranodal vaccination. No advantage of additional IL-2 treatment could be shown. Clin Cancer Res; 17(17); 5725–35. ©2011 AACR.

Published

2023

31. Supplementary Figure 2 from Vaccination with mRNA-Electroporated Dendritic Cells Induces Robust Tumor Antigen-Specific CD4+ and CD8+ T Cells Responses in Stage III and IV Melanoma Patients

Author

Gosse J. Adema, Cornelis J. A. Punt, Carl G. Figdor, I. Jolanda M. de Vries, Kris Thielemans, Roel Mus, Danita H. Schuurhuis, Tjitske Duiveman-de Boer, Joannes F. M. Jacobs, Willeke A. M. Blokx, Michelle M. van Rossum, Johannes H. W. de Wilt, Alexandra J. Croockewit, W. Joost Lesterhuis, Kalijn Bol, Gerty Schreibelt, and Erik H. J. G. Aarntzen

Abstract

PDF file, 1359K, Vaccine characteristics of first cycle of all patients. (A) Expression of HLA-ABC, HLA-DR/DP, HLA-DQ, CD80, CD86, CD83, and CCR7 was analyzed by flow cytometry. (B) Tumor antigen expression by DCs 2-4 hrs after electroporation with mRNA encoding gp100 and tyrosinase. Data are shown as percentage of positive DCs used for the first vaccination. The graphs represent mean � SD of all patients.

Published

2023

32. Data from Effective Clinical Responses in Metastatic Melanoma Patients after Vaccination with Primary Myeloid Dendritic Cells

Author

I. Jolanda M. de Vries, Carl G. Figdor, Cornelis J.A. Punt, Winald R. Gerritsen, Christian U. Blank, Sander Kelderman, Joannes F.M. Jacobs, Rutger H.T. Koornstra, Sandra A.J. Croockewit, Roel D.M. Mus, Marieke E.B. Welzen, Michelle M. van Rossum, Willeke A.M. Blokx, Katja Petry, Gregor Winkels, Jurjen Tel, Tom G.M. van Oorschot, Michel A.M. Olde Nordkamp, Jeanette M. Pots, Annemiek J. de Boer, Nicole M. Scharenborg, Mandy W.M.M. van de Rakt, Tjitske Duiveman-de Boer, Erik H.J.G. Aarntzen, Florian Wimmers, Harm Westdorp, Kalijn F. Bol, and Gerty Schreibelt

Abstract

Purpose: Thus far, dendritic cell (DC)-based immunotherapy of cancer was primarily based on in vitro–generated monocyte-derived DCs, which require extensive in vitro manipulation. Here, we report on a clinical study exploiting primary CD1c+ myeloid DCs, naturally circulating in the blood.Experimental Design: Fourteen stage IV melanoma patients, without previous systemic treatment for metastatic disease, received autologous CD1c+ myeloid DCs, activated by only brief (16 hours) ex vivo culture and loaded with tumor-associated antigens of tyrosinase and gp100.Results: Our results show that therapeutic vaccination against melanoma with small amounts (3–10 × 106) of myeloid DCs is feasible and without substantial toxicity. Four of 14 patients showed long-term progression-free survival (12–35 months), which directly correlated with the development of multifunctional CD8+ T-cell responses in three of these patients. In particular, high CD107a expression, indicative for cytolytic activity, and IFNγ as well as TNFα and CCL4 production was observed. Apparently, these T-cell responses are essential to induce tumor regression and promote long-term survival by stalling tumor growth.Conclusions: We show that vaccination of metastatic melanoma patients with primary myeloid DCs is feasible and safe and results in induction of effective antitumor immune responses that coincide with improved progression-free survival. Clin Cancer Res; 22(9); 2155–66. ©2015 AACR.

Published

2023

33. Data from Targeting of 111In-Labeled Dendritic Cell Human Vaccines Improved by Reducing Number of Cells

Author

I. Jolanda M. de Vries, Wim J. Oyen, Carl G. Figdor, Arend Heerschap, Gosse J. Adema, Cornelius J.A. Punt, Maichel van Riel, W. Joost Lesterhuis, Mandy van de Rakt, Gerty Schreibelt, Pauline Verdijk, Luis J. Cruz, Fernando Bonetto, Mangala Srinivas, and Erik H.J.G. Aarntzen

Abstract

Purpose: Anticancer dendritic cell (DC) vaccines require the DCs to relocate to lymph nodes (LN) to trigger immune responses. However, these migration rates are typically very poor. Improving the targeting of ex vivo generated DCs to LNs might increase vaccine efficacy and reduce costs. We investigated DC migration in vivo in humans under different conditions.Experimental Design:HLA-A*02:01 patients with melanoma were vaccinated with mature DCs loaded with tyrosinase and gp100 peptides together with keyhole limpet hemocyanin (NCT00243594). For this study, patients received an additional intradermal vaccination with 111In-labeled mature DCs. The injection site was pretreated with nonloaded, activated DCs, TNFα, or Imiquimod; granulocyte macrophage colony-stimulating factor was coinjected or smaller numbers of DCs were injected. Migration was measured by scintigraphy and compared with an intrapatient control vaccination. In an ex vivo tissue model, we measured CCL21-directed migration of 19F-labeled DCs over a period of up to 12 hours using 19F MRI to supplement our patient data.Results: Pretreatment of the injection site induced local inflammatory reactions but did not improve migration rates. Both in vitro and in vivo, reduction of cell numbers to 5 × 106 or less cells per injection improved migration. Furthermore, scintigraphy is insufficient to study migration of such small numbers of 111In-labeled DCs in vivo.Conclusion: Reduction of cell density, not pretreatment of the injection site, is crucial for improved migration of DCs to LNs in vivo. Clin Cancer Res; 19(6); 1525–33. ©2013 AACR.

Published

2023

34. Supplementary Figure 1 from Effective Clinical Responses in Metastatic Melanoma Patients after Vaccination with Primary Myeloid Dendritic Cells

Author

I. Jolanda M. de Vries, Carl G. Figdor, Cornelis J.A. Punt, Winald R. Gerritsen, Christian U. Blank, Sander Kelderman, Joannes F.M. Jacobs, Rutger H.T. Koornstra, Sandra A.J. Croockewit, Roel D.M. Mus, Marieke E.B. Welzen, Michelle M. van Rossum, Willeke A.M. Blokx, Katja Petry, Gregor Winkels, Jurjen Tel, Tom G.M. van Oorschot, Michel A.M. Olde Nordkamp, Jeanette M. Pots, Annemiek J. de Boer, Nicole M. Scharenborg, Mandy W.M.M. van de Rakt, Tjitske Duiveman-de Boer, Erik H.J.G. Aarntzen, Florian Wimmers, Harm Westdorp, Kalijn F. Bol, and Gerty Schreibelt

Abstract

Supplementary Figure 1. Schematic overview of the 44 h mDC vaccine preparation cycle and vaccination strategy.

Published

2023

35. Supplementary Figures S1-S12 from Expansion of a BDCA1+CD14+ Myeloid Cell Population in Melanoma Patients May Attenuate the Efficacy of Dendritic Cell Vaccines

Author

I. Jolanda M. de Vries, Carl G. Figdor, Evelien L. Smits, Christoph Schröder, Tjitske Duiveman-de Boer, Ruurd Torensma, Simone P. Sittig, Gerty Schreibelt, Annette E. Sköld, Stanleyson V. Hato, Altuna Halilovic, Mark A.J. Gorris, Sonja I. Buschow, and Ghaith Bakdash

Abstract

The gating strategy applied to isolate and determine the frequency of BDCA1+ DCs, BDCA1+ CD14+ cells, monocytes and MDSCs from PBMCS of melanoma patients or healthy donors by FACS (S1); The distribution of potentially "missed genes" over the RPKM value spectrum in all samples that underwent RNA sequencing (S2); A Venn diagram displaying the overlap between the four gene sets used in GSEA analysis: Mono high, infDC high, MoDC sig and BDCA1+ DC high (S3); The T cell suppressive capacity of BDCA1+ DCs, BDCA1+ CD14+ cells, monocytes and MDSCs (S4); Quantification of immunofluorescence stainings performed on sections of paraffin-embedded resection specimens of healthy and melanoma metastasized lymph nodes or healthy and melanoma metastasized colon (S5); Large view, showing multiple cells, of May-Grunwald/Giemsa-stained healthy donor-derived, FACS-sorted BDCA1+ DCs, BDCA1+CD14+ cells and monocytes (S6); GSEA enrichment plots (S7); BDCA1+ DCs, BDCA1+CD14+ cells and monocytes respond to TLR2 and TLR8 stimulation (S8); IL-12 levels determined in overnight supernatants of BDCA1+ DCs, BDCA1+ CD14+ cells and monocytes cultures following stimulation with pIC and R848 (S9); The T cell polarizing capacity of BDCA1+ DCs, BDCA1+ CD14+ cells and monocytes (S10); The effect of IL-10 on BDCA1+ CD14+ cell-induced T cell proliferation was determined by performing an MLR with allogenic naïve CD4+ T cells in the presence or absence of anit-IL-10 and anti-IL10 receptor or the matching isotype controls (S11); The suppressive capacity of BDCA1+ CD14+ cells is not reversed by PD-L1 blocking (S12).

Published

2023

36. Supplementary Figure 2 from Natural Human Plasmacytoid Dendritic Cells Induce Antigen-Specific T-Cell Responses in Melanoma Patients

Author

I. Jolanda M. de Vries, Carl G. Figdor, Cornelis J.A. Punt, Pierre G. Coulie, Gregor Winkels, Michelle van Rossum, Wim J.G. Oyen, Sandra Croockewit, Otto C. Boerman, Daniel Benitez-Ribas, Barbara M. Schulte, Gerty Schreibelt, Tetsuro Baba, Erik H.J.G. Aarntzen, and Jurjen Tel

Abstract

Supplementary Figure 2 PDF file - 46K, Supplementary Figure 2 Plasmacytoid DCs acquire CCL21-driven chemotactic ability upon activation

Published

2023

37. Supplementary Legends for Figures 1-3, Table 1 from Targeting CD4+ T-Helper Cells Improves the Induction of Antitumor Responses in Dendritic Cell–Based Vaccination

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, William W. Kwok, Michelle M. Van Rossum, Willeke A.M. Blokx, Alexandra Croockewit, Dirk Schadendorf, John B.A.G. Haanen, Johannes H.W. De Wilt, Roel Mus, Gerty Schreibelt, Kalijn Bol, Joannes F.M. Jacobs, Danita Schuurhuis, W. Joost Lesterhuis, I. Jolanda M. De Vries, and Erik H.J.G. Aarntzen

Abstract

PDF file - 43K

Published

2023

38. Supplementary Figure Legends 1-5 from Skin-Test Infiltrating Lymphocytes Early Predict Clinical Outcome of Dendritic Cell–Based Vaccination in Metastatic Melanoma

Author

I. Jolanda M. De Vries, Cornelis J.A. Punt, Carl G. Figdor, Gosse J. Adema, Michelle M. Van Rossum, W. Joost Lesterhuis, Joannes F.M. Jacobs, Gerty Schreibelt, Kalijn Bol, and Erik H.J.G. Aarntzen

Abstract

PDF file - 48K

Published

2023

39. Supplementary Figure 1 from Natural Human Plasmacytoid Dendritic Cells Induce Antigen-Specific T-Cell Responses in Melanoma Patients

Author

I. Jolanda M. de Vries, Carl G. Figdor, Cornelis J.A. Punt, Pierre G. Coulie, Gregor Winkels, Michelle van Rossum, Wim J.G. Oyen, Sandra Croockewit, Otto C. Boerman, Daniel Benitez-Ribas, Barbara M. Schulte, Gerty Schreibelt, Tetsuro Baba, Erik H.J.G. Aarntzen, and Jurjen Tel

Abstract

Supplementary Figure 1 PDF file - 34K, Supplementary Figure 1 CliniMACS-based pDC isolation is feasible

Published

2023

40. Supplementary Figure 3 from Targeting CD4+ T-Helper Cells Improves the Induction of Antitumor Responses in Dendritic Cell–Based Vaccination

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, William W. Kwok, Michelle M. Van Rossum, Willeke A.M. Blokx, Alexandra Croockewit, Dirk Schadendorf, John B.A.G. Haanen, Johannes H.W. De Wilt, Roel Mus, Gerty Schreibelt, Kalijn Bol, Joannes F.M. Jacobs, Danita Schuurhuis, W. Joost Lesterhuis, I. Jolanda M. De Vries, and Erik H.J.G. Aarntzen

Abstract

PDF file - 34K, KLH specific responses

Published

2023

41. Supplementary Dataset S1 from Expansion of a BDCA1+CD14+ Myeloid Cell Population in Melanoma Patients May Attenuate the Efficacy of Dendritic Cell Vaccines

Author

I. Jolanda M. de Vries, Carl G. Figdor, Evelien L. Smits, Christoph Schröder, Tjitske Duiveman-de Boer, Ruurd Torensma, Simone P. Sittig, Gerty Schreibelt, Annette E. Sköld, Stanleyson V. Hato, Altuna Halilovic, Mark A.J. Gorris, Sonja I. Buschow, and Ghaith Bakdash

Abstract

The detailed composition of all gene sets used in GSEA.

Published

2023

42. Supplementary Figure 2 from Targeting CD4+ T-Helper Cells Improves the Induction of Antitumor Responses in Dendritic Cell–Based Vaccination

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, William W. Kwok, Michelle M. Van Rossum, Willeke A.M. Blokx, Alexandra Croockewit, Dirk Schadendorf, John B.A.G. Haanen, Johannes H.W. De Wilt, Roel Mus, Gerty Schreibelt, Kalijn Bol, Joannes F.M. Jacobs, Danita Schuurhuis, W. Joost Lesterhuis, I. Jolanda M. De Vries, and Erik H.J.G. Aarntzen

Abstract

PDF file - 40K, Vaccine characteristics

Published

2023

43. Supplementary Figure 2 from Skin-Test Infiltrating Lymphocytes Early Predict Clinical Outcome of Dendritic Cell–Based Vaccination in Metastatic Melanoma

Author

I. Jolanda M. De Vries, Cornelis J.A. Punt, Carl G. Figdor, Gosse J. Adema, Michelle M. Van Rossum, W. Joost Lesterhuis, Joannes F.M. Jacobs, Gerty Schreibelt, Kalijn Bol, and Erik H.J.G. Aarntzen

Abstract

PDF file - 233K, Definition of criteria for SKIL culture evaluation: Three examples are shown to illustrate the definition of SKIL culture criteria. (A) Criterion III, one patient (IV-B-16-St) with a clear population of TAA-specific CD8+ T cells in SKIL cultures, which produce high levels of IFNg upon encounter of both the defined gp100 peptides and naturally processed gp100 presented by a HLA-A*02:01 positive melanoma cell line (Mel624). Moderate amounts of IL-2 are produced and minimal production of IL-5, representing a clear IFNg dominant cytokine profile. (B) Criterion II, a patient (IV-B-11-Ro) with TAA-specific CD8+ T cells in SKIL cultures which produce high levels of IFNg and IL-2 upon encounter of the gp100 peptide, but fail to recognize the naturally processed gp100. (C) Criterion I, a patient (IV-A-07-Th) with a population of TAA-specific CD8+ T cells in SKIL cultures, recognizing the g100-154 peptide, but not the naturally processed gp100. Furthermore, those TAA-specific CD8+ T cells do not produce IFNg but produce elevated levels of IL-5 instead, indicating that the immune system is skewed towards tumor tolerance

Published

2023

44. Data from Expansion of a BDCA1+CD14+ Myeloid Cell Population in Melanoma Patients May Attenuate the Efficacy of Dendritic Cell Vaccines

Author

I. Jolanda M. de Vries, Carl G. Figdor, Evelien L. Smits, Christoph Schröder, Tjitske Duiveman-de Boer, Ruurd Torensma, Simone P. Sittig, Gerty Schreibelt, Annette E. Sköld, Stanleyson V. Hato, Altuna Halilovic, Mark A.J. Gorris, Sonja I. Buschow, and Ghaith Bakdash

Abstract

The tumor microenvironment is characterized by regulatory T cells, type II macrophages, myeloid-derived suppressor cells, and other immunosuppressive cells that promote malignant progression. Here we report the identification of a novel BDCA1+CD14+ population of immunosuppressive myeloid cells that are expanded in melanoma patients and are present in dendritic cell–based vaccines, where they suppress CD4+ T cells in an antigen-specific manner. Mechanistic investigations showed that BDCA1+CD14+ cells expressed high levels of the immune checkpoint molecule PD-L1 to hinder T-cell proliferation. While this BDCA1+CD14+ cell population expressed markers of both BDCA1+ dendritic cells and monocytes, analyses of function, transcriptome, and proteome established their unique nature as exploited by tumors for immune escape. We propose that targeting these cells may improve the efficacy of cancer immunotherapy. Cancer Res; 76(15); 4332–46. ©2016 AACR.

Published

2023

45. Supplementary Table S2 from Expansion of a BDCA1+CD14+ Myeloid Cell Population in Melanoma Patients May Attenuate the Efficacy of Dendritic Cell Vaccines

Author

I. Jolanda M. de Vries, Carl G. Figdor, Evelien L. Smits, Christoph Schröder, Tjitske Duiveman-de Boer, Ruurd Torensma, Simone P. Sittig, Gerty Schreibelt, Annette E. Sköld, Stanleyson V. Hato, Altuna Halilovic, Mark A.J. Gorris, Sonja I. Buschow, and Ghaith Bakdash

Abstract

GSEA raw data generated by Bubble GUM software.

Published

2023

46. Supplementary Figure 5 from Skin-Test Infiltrating Lymphocytes Early Predict Clinical Outcome of Dendritic Cell–Based Vaccination in Metastatic Melanoma

Author

I. Jolanda M. De Vries, Cornelis J.A. Punt, Carl G. Figdor, Gosse J. Adema, Michelle M. Van Rossum, W. Joost Lesterhuis, Joannes F.M. Jacobs, Gerty Schreibelt, Kalijn Bol, and Erik H.J.G. Aarntzen

Abstract

PDF file - 73K, Patient selection based on SKIL criteria: SKIL criteria are applied to select patients with immune responses meeting increasingly stringent criteria

Published

2023

47. Supplementary Table 1 from Targeting CD4+ T-Helper Cells Improves the Induction of Antitumor Responses in Dendritic Cell–Based Vaccination

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, William W. Kwok, Michelle M. Van Rossum, Willeke A.M. Blokx, Alexandra Croockewit, Dirk Schadendorf, John B.A.G. Haanen, Johannes H.W. De Wilt, Roel Mus, Gerty Schreibelt, Kalijn Bol, Joannes F.M. Jacobs, Danita Schuurhuis, W. Joost Lesterhuis, I. Jolanda M. De Vries, and Erik H.J.G. Aarntzen

Abstract

PDF file - 52K, Characteristics matched controls

Published

2023

48. Supplementary Figure 1 from Targeting CD4+ T-Helper Cells Improves the Induction of Antitumor Responses in Dendritic Cell–Based Vaccination

Author

Carl G. Figdor, Cornelis J.A. Punt, Gosse J. Adema, William W. Kwok, Michelle M. Van Rossum, Willeke A.M. Blokx, Alexandra Croockewit, Dirk Schadendorf, John B.A.G. Haanen, Johannes H.W. De Wilt, Roel Mus, Gerty Schreibelt, Kalijn Bol, Joannes F.M. Jacobs, Danita Schuurhuis, W. Joost Lesterhuis, I. Jolanda M. De Vries, and Erik H.J.G. Aarntzen

Abstract

PDF file - 51K, CONSORT flow chart

Published

2023

49. Supplementary Figure 3 from Skin-Test Infiltrating Lymphocytes Early Predict Clinical Outcome of Dendritic Cell–Based Vaccination in Metastatic Melanoma

Author

I. Jolanda M. De Vries, Cornelis J.A. Punt, Carl G. Figdor, Gosse J. Adema, Michelle M. Van Rossum, W. Joost Lesterhuis, Joannes F.M. Jacobs, Gerty Schreibelt, Kalijn Bol, and Erik H.J.G. Aarntzen

Abstract

PDF file - 71K, KLH-specific T cell responses according to SKIL classification: Regardless of the number of epitopes or the increasingly stringent criteria for TAA-specific immune responses; the levels of KLH-specific T cell responses were similar and highly variable between individuals. One-way ANOVA was used for comparison of KLH-specific T cell responses in groups of patients with increasing breadth of TAA-specific CD8+ T cell responses. Student t-test was used for comparison of KLH-specific T cell responses in groups of patients as defined by different SKIL criteria

Published

2023

50. Supplementary Table 1 from Natural Human Plasmacytoid Dendritic Cells Induce Antigen-Specific T-Cell Responses in Melanoma Patients

Author

I. Jolanda M. de Vries, Carl G. Figdor, Cornelis J.A. Punt, Pierre G. Coulie, Gregor Winkels, Michelle van Rossum, Wim J.G. Oyen, Sandra Croockewit, Otto C. Boerman, Daniel Benitez-Ribas, Barbara M. Schulte, Gerty Schreibelt, Tetsuro Baba, Erik H.J.G. Aarntzen, and Jurjen Tel

Abstract

Supplementary Table 1 PDF file - 29K, Induration (mm) of the different injection sites in the DTH skin test

Published

2023