Your search keyword '"Tumor Immunology and Immunotherapy Program"' showing total 18 results

1. Defining the critical hurdles in cancer immunotherapy

Author

Andrea Nicolini, Francesco M. Marincola, William E. Carson, Paolo A. Ascierto, Michele Maio, Jedd D. Wolchok, Michael T. Lotze, Jirina Bartunkova, Weihua Xiao, Hauke Winter, Barbara Seliger, Jon M. Wigginton, Cedrik M. Britten, Ignacio Melero, Guido Kroemer, Neil L. Berinstein, Jill O'Donnell-Tormey, Heinz Zwierzina, Lothar Bergmann, Lloyd J. Old, Christian H. Ottensmeier, Jérôme Galon, Per thor Straten, Koji Kawakami, Michael Papamichail, Yutaka Kawakami, Michael I. Nishimura, Mary L. Disis, Steinar Aamdal, C. J. M. Melief, Pedro Romero, Kristen Hege, Wenru Song, Pawel Kalinski, Jonathan L. Bramson, Harpreet Singh-Jasuja, Jens Peter Marschner, Bernard A. Fox, Samir N. Khleif, Brad H. Nelson, Marij J. P. Welters, Elizabeth M. Jaffee, Patrick Hwu, Rik J. Scheper, Robert C. Rees, Giuseppe Masucci, Hideaki Tahara, Cristina Bonorino, Glenn Dranoff, Ernest C. Borden, William J. Murphy, Zhigang Tian, Michael B. Atkins, Robert O. Dillman, Thomas F. Gajewski, Hiroshi Shiku, Leif Håkansson, Michael J. Mastrangelo, Lisa H. Butterfield, Shukui Qin, Laurence Zitvogel, Harry Dolstra, Michele Guida, George Coukos, Mohamed L. Salem, Xuetao Cao, Giorgio Parmiani, Enrico Proietti, Ena Wang, Sylvia Janetzki, A. Raja Choudhury, Gerd Ritter, Hyam I. Levitsky, Kunle Odunsi, Kohzoh Imai, Paul von Hoegen, Christoph Huber, Réjean Lapointe, Antoni Ribas, Dolores J. Schendel, Pamela S. Ohashi, Beatrix Kotlan, Cécile Gouttefangeas, James H. Finke, Alfred E. Chang, Howard L. Kaufman, Lindy G. Durrant, Sjoerd H. van der Burg, Jared Gollob, Dainius Characiejus, Tara Withington, Padmanee Sharma, Ronald B. Herberman, Cristina Maccalli, Ulrich Keilholtz, Axel Hoos, Graham Pawelec, Fabio Grizzi, Tanja D. de Gruijl, F. Stephen Hodi, Ruggero Ridolfi, James P. Allison, Licia Rivoltini, Carl H. June, Rolf Kiessling, Department of Molecular Microbiology and Immunology, Oregon Health and Science University [Portland] (OHSU)-Knight Cancer Institute, Earle A. Chiles Research Institute, Providence Portland Medical Center-Robert W. Franz Research Center-Providence Cancer Center, Clinical Cooperation Group 'Immune Monitoring', German Research Center for Environmental Health-Helmholtz Centre Munich-Institute of Molecular Immunology, Division of Hematology Oncology, University of Pittsburgh Cancer Institute-Departments of Medicine, Department of Surgery, Cancer Institute-University of Pittsburgh (PITT), Pennsylvania Commonwealth System of Higher Education (PCSHE)-Pennsylvania Commonwealth System of Higher Education (PCSHE), Department of Immunology, University of Pittsburgh Cancer Institute, Department of Clinical Cancer Research, The Norwegian Radium Hospital-Oslo University Hospital [Oslo], Memorial Sloane Kettering Cancer Center [New York], Howard Hughes Medical Institute (HHMI), Medical Oncology and Innovative Therapy, Instituto Nazionale Tumori-Fondazione 'G. Pascale', Beth Israel Deaconess Medical Center, Harvard Medical School [Boston] (HMS), Institute of Immunology, Charles University [Prague] (CU)-FOCIS Center of Excellence-2nd Medical School, Goethe-Universität Frankfurt am Main, IRX Therapeutics, Stanford University-ImmunoVaccine Inc., Instituto Nacional para o Controle do Câncer, Instituto de Pesquisas Biomédicas-PUCRS Faculdade de Biociências, Department of Solid Tumor Oncology, Cleveland Clinic, Department of Translational Hematology and Oncology Research, Department of Pathology, McMaster University [Hamilton, Ontario], University Medical Center Mainz, III. Medical Department, Ribological GmbH, Department of Medicine-University Medical Center of the Johannes Gutenberg-University-Clinical Development, BioNTech AG, Chinese Academy of Medical Sciences, Second Military Medical University-National Key Laboratory of Medical Immunology, Ohio State University [Columbus] (OSU), University of Michigan [Ann Arbor], University of Michigan System-University of Michigan System, Institute of Oncology, Vilnius University [Vilnius]-Faculty of Medicine, Department of Medicine, University of Queensland [Brisbane], Ovarian Cancer Research Center, Perelman School of Medicine, University of Pennsylvania [Philadelphia]-University of Pennsylvania [Philadelphia], Department of Medical Oncology, VU Medical Center-Cancer Center Amsterdam, Hoag Institute for Research and Education, Hoag Cancer Institute, Department of Laboratory Medicine, Radboud university [Nijmegen]-Nijmegen Centre for Molecular Life Sciences-Nijmegen Medical Centre [Nijmegen], Brigham and Women's Hospital [Boston], Dana-Farber Cancer Institute [Boston], Academic Department of Clinical Oncology, University of Nottingham, UK (UON), Centre de Recherche des Cordeliers (CRC (UMR_S 872)), Université Paris Descartes - Paris 5 (UPD5)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Alnylam Pharmaceuticals, Inc., Institute for Cell Biology, Istituto Clinico Humanitas [Milan] (IRCCS Milan), Humanitas University [Milan] (Hunimed), Oncology Department, University of Lund, CanImGuide Therapeutics AB, University of California [San Francisco] (UCSF), University of California, Intrexon Corporation, Germantown, Bristol-Myers Squibb Company, Translational Oncology & Immunology, Centre TRON at the Mainz University Medical Center, Department of Melanoma Medical Oncology, The University of Texas M.D. Anderson Cancer Center [Houston], The Institute of Medical Science, The University of Tokyo (UTokyo), Department of Oncology, The Sidney Kimmel Comprehensive Cancer Center, Johns Hopkins University School of Medicine [Baltimore]-Johns Hopkins University School of Medicine [Baltimore], ZellNet Consulting, Pathology and Laboratory Medicine, University of Pennsylvania [Philadelphia], Rush University Cancer Center, Rush University Medical Center [Chicago], School of Medicine and Public Health, Kyoto University [Kyoto], Division of Cellular Signaling, Institute for Advanced Medical Research, Dept. of Hematology and Medical Oncology, Charité Comprehensive Cancer Center, Cancer Vaccine Section, NCI, Department of Oncology - Pathology, Cancer Center Karolinska [Karolinska Institutet] (CCK), Karolinska Institutet [Stockholm]-Karolinska Institutet [Stockholm], Department of Molecular Immunology and Toxicology, Center of Surgical and Molecular Tumor pathology, Centre de Recherche du Centre Hospitalier de l’Université de Montréal (CR CHUM), Centre Hospitalier de l'Université de Montréal (CHUM), Université de Montréal (UdeM)-Université de Montréal (UdeM), School of Medicine, Johns Hopkins University (JHU)-Oncology Center, Department of Molecular Oncology, Foundation San Raffaele Scientific Institute, Medical Oncology and Immunotherapy, Istituto Toscano Tumori-University Hospital of Siena-Department of Oncology, Merck KGaA, Merck & Co. Inc, Thomas Jefferson University, Department of Oncology-Pathology, karolinska institute, CIMA, CUN and Medical School University of Navarra, Department of Immunohematology and Blood Transfusion, Leiden University Medical Center (LUMC), Davis Medical Center, Sacramento-University of California, Deeley Research Centre, BC Cancer Agency (BCCRC), Department of Internal Medicine, University of Pisa - Università di Pisa, Oncology Institute, Loyola University Medical Center (LUMC)-Cardinal Bernardin Cancer Center, Tumor Immunology and Immunotherapy Program, Roswell Park Cancer Institute [Buffalo]-Department of Gynecologic Oncology, Ontario Cancer Institute, University Health Network, Cancer Immunotherapy Consortium (CIC), Cancer Research Institute, Cancer Research, Ludwig Institute, Experimental Cancer Medicine Centre, University of Southampton-Faculty of Medicine, Cancer Immunology and Immunotherapy Center, Saint Savas Cancer Hospital, Unit of Immuno-Biotherapy of Melanoma and Solid Tumors, San Raffaele Scientific Institute, Center for Medical Research, Eberhard Karls Universität Tübingen = Eberhard Karls University of Tuebingen, Department of Cell Biology and Neurosciences, Istituto Superiore di Sanita', Chinese PLA Cancer Center, Department of Oncology-The Eighty-First Hospital, The John van Geest Cancer Research Centre, School of Science and Technology-Nottingham Trent University, Jonsson Comprehensive Cancer Center, Immunoterapia e Terapia Cellulare Somatica, Istituto Scientifico Romagnolo per lo Studio e la Cura dei Tumori (I.R.S.T.), Unit of Immunotherapy of Human Tumors, Istituto Nazionale Tumori-IRCCS Foundation, Division of Clinical Onco-Immunology, Université de Lausanne (UNIL)-Ludwig Center for Cancer Research, Immunology and Biotechnology Unit, Faculty of Science-Department of Zoology-Tanta University, VU University Medical Center [Amsterdam], Institute of Medical Immunology, Martin-Luther-Universität Halle Wittenberg (MLU), Departments of Immunology, Department of Cancer Vaccine, Mie University, Department of Immuno-gene Therapy, Immatics Biotechnologies GmbH, Eberhard Karls Universität Tübingen = Eberhard Karls University of Tuebingen-Department of Immunology-Institute for Cell Biology, Millennium: The Takeda Oncology Company, Pfizer Oncology, Center for Cancer Immune Therapy (CCIT), Herlev and Gentofte Hospital-Department of Hematology, Department of Surgery and Bioengineering, The University of Tokyo (UTokyo)-Institute of Medical Science-Advanced Clinical Research Center, School of Life Sciences-University of Science & Technology of China [Suzhou], Institute of Immunopharmacology & Immunotherapy, Shandong University-School of Pharmaceutical Sciences, Experimental Cancer Immunology and Therapy, Leiden University Medical Center (LUMC)-Department of Clinical Oncology, Euraccine Consulting Group, Infectious Disease and Immunogenetics Section (IDIS), Department of Transfusion Medicine-Clinical Center-National Institute of Health NIH), Center for Human Immunology (CHI), National Institute of Health (NIH), Leiden University Medical Center (LUMC)-Department of Clinical Oncology (K1-P), Ludwig Maximilians University-Klinikum Grosshadern, Biological Therapy of Cancer, Medical and Surgical Services Organizations-International Society For Biological Therapy Of Cancer, School of Life Science-University of Science and Technology of China [Hefei] (USTC), Immunologie des tumeurs et immunothérapie (UMR 1015), Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut Gustave Roussy (IGR)-Université Paris-Sud - Paris 11 (UP11), Department Haematology and Oncology, Innsbruck Medical University [Austria] (IMU), Medical Center, University of Chicago, Discovery Medicine-Oncology, Tumor Vaccine Group, University of Washington [Seattle]-Center for Translational Medicine in Women's Health, The work of CIMT-CIP was supported by a grant from the Wallace Coulter foundation (Florida, USA)., Helmholtz Centre Munich-Institute of Molecular Immunology-Helmholtz Zentrum München = German Research Center for Environmental Health, University of Pennsylvania-University of Pennsylvania, Radboud University [Nijmegen]-Nijmegen Centre for Molecular Life Sciences-Nijmegen Medical Centre [Nijmegen], Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Lund University [Lund], University of California [San Francisco] (UC San Francisco), University of California (UC), University of Pennsylvania, Kyoto University, Sacramento-University of California (UC), Université de Lausanne = University of Lausanne (UNIL)-Ludwig Center for Cancer Research, Klinikum Grosshadern-Ludwig-Maximilians University [Munich] (LMU), University of Science and Technology of China [Hefei] (USTC)-School of Life Science, Université Paris-Sud - Paris 11 (UP11)-Institut Gustave Roussy (IGR)-Institut National de la Santé et de la Recherche Médicale (INSERM), Innsbruck Medical University = Medizinische Universität Innsbruck (IMU), BMC, Ed., Computer Systems, Medical oncology laboratory, Pathology, CCA - Immuno-pathogenesis, CCA - Innovative therapy, Oregon Health and Science University-Knight Cancer Institute, Cancer Institute-University of Pittsburgh, The Norwegian Radium Hospital-Oslo University Hospital, Memorial Sloan-Kettering Cancer Center, Sloan-Kettering Institute, Howard Hughes Medical Institute, Ludwig Center for Cancer Immunotherapy, A Teaching Hospital of Harvard Medical School, Charles University [Prague]-FOCIS Center of Excellence-2nd Medical School, Stanford University [Stanford]-ImmunoVaccine Inc., Ohio State University [Columbus] ( OSU ), University of Michigan Medical Center, University of Pennsylvania Medical Center, Radboud university [Nijmegen]-Nijmegen Centre for Molecular Life Sciences-Nijmegen Medical Centre, University of Nottingham, UK ( UON ), Cleveland Clinic Foundation, Centre de Recherche des Cordeliers ( CRC (UMR_S 872) ), Université Pierre et Marie Curie - Paris 6 ( UPMC ) -Université Paris Descartes - Paris 5 ( UPD5 ) -Institut National de la Santé et de la Recherche Médicale ( INSERM ) -Centre National de la Recherche Scientifique ( CNRS ), Istituto Clinico Humanitas [Milan] ( IRCCS Milan ), Humanitas University [Milan] ( Hunimed ), University of California [San Francisco] ( UCSF ), Harvard Medical School [Boston] ( HMS ), MD Anderson Cancer Center, The University of Tokyo, Rush University Medical Center, Cancer Center Karolinska [Karolinska Institutet] ( CCK ), Centre Hospitalier de l'Université de Montréal-Hôpital Notre-Dame Research Center ( CRCHUM ), Department of Medicine-University of Montreal, Johns Hopkins University ( JHU ) -Oncology Center, BC Cancer Agency ( BCCRC ), University of Pisa [Pisa], Loyola University Medical Center ( LUMC ) -Cardinal Bernardin Cancer Center, Cancer Immunotherapy Consortium ( CIC ), University of Southampton [Southampton]-Faculty of Medicine, Eberhard Karls Universität Tübingen, University of Lausanne-Ludwig Center for Cancer Research, Martin-Luther-University Halle-Wittenberg, Mie University Graduate School of Medicine, Eberhard Karls Universität Tübingen-Department of Immunology-Institute for Cell Biology, Center for Cancer Immune Therapy ( CCIT ), Herlev Hospital-Department of Hematology, The University of Tokyo-Institute of Medical Science-Advanced Clinical Research Center, Infectious Disease and Immunogenetics Section ( IDIS ), Center for Human Immunology ( CHI ), University of Science and Technology of China [Hefei] ( USTC ) -School of Life Science, Immunologie des tumeurs et immunothérapie ( UMR 1015 ), Université Paris-Sud - Paris 11 ( UP11 ) -Institut Gustave Roussy ( IGR ) -Institut National de la Santé et de la Recherche Médicale ( INSERM ), Innsbruck Medical University [Austria] ( IMU ), Department of Medicine-Clinical Development, BioNTech AG-Johannes Gutenberg - Universität Mainz = Johannes Gutenberg University (JGU), Universiteit Leiden-Universiteit Leiden, Roswell Park Cancer Institute [Buffalo] (RPCI)-Department of Gynecologic Oncology, Istituto Superiore di Sanità (ISS), Istituto Scientifico Romagnolo per lo Studio e la Cura dei Tumori (IRST) IRCCS, Universiteit Leiden-Universiteit Leiden-Department of Clinical Oncology, and Universiteit Leiden-Universiteit Leiden-Department of Clinical Oncology (K1-P)

Subjects

medicine.medical_specialty, International Cooperation, medicine.medical_treatment, Alternative medicine, lcsh:Medicine, Translational research, [SDV.CAN]Life Sciences [q-bio]/Cancer, Cancer Immunotherapy, General Biochemistry, Genetics and Molecular Biology, [ SDV.CAN ] Life Sciences [q-bio]/Cancer, Translational Research, Biomedical, 03 medical and health sciences, SDG 17 - Partnerships for the Goals, 0302 clinical medicine, Cancer immunotherapy, [SDV.CAN] Life Sciences [q-bio]/Cancer, [ SDV.MHEP ] Life Sciences [q-bio]/Human health and pathology, Neoplasms, medicine, Humans, In patient, 030304 developmental biology, Medicine(all), 0303 health sciences, geography, Summit, geography.geographical_feature_category, [SDV.MHEP] Life Sciences [q-bio]/Human health and pathology, Biochemistry, Genetics and Molecular Biology(all), business.industry, lcsh:R, Cancer, General Medicine, Public relations, medicine.disease, 3. Good health, Clinical trial, Immunotherapy, Neoplasms/therapy, Translational Medical Research, 030220 oncology & carcinogenesis, Immunology, Commentary, Working group, business, [SDV.MHEP]Life Sciences [q-bio]/Human health and pathology

Abstract

Scientific discoveries that provide strong evidence of antitumor effects in preclinical models often encounter significant delays before being tested in patients with cancer. While some of these delays have a scientific basis, others do not. We need to do better. Innovative strategies need to move into early stage clinical trials as quickly as it is safe, and if successful, these therapies should efficiently obtain regulatory approval and widespread clinical application. In late 2009 and 2010 the Society for Immunotherapy of Cancer (SITC), convened an "Immunotherapy Summit" with representatives from immunotherapy organizations representing Europe, Japan, China and North America to discuss collaborations to improve development and delivery of cancer immunotherapy. One of the concepts raised by SITC and defined as critical by all parties was the need to identify hurdles that impede effective translation of cancer immunotherapy. With consensus on these hurdles, international working groups could be developed to make recommendations vetted by the participating organizations. These recommendations could then be considered by regulatory bodies, governmental and private funding agencies, pharmaceutical companies and academic institutions to facilitate changes necessary to accelerate clinical translation of novel immune-based cancer therapies. The critical hurdles identified by representatives of the collaborating organizations, now organized as the World Immunotherapy Council, are presented and discussed in this report. Some of the identified hurdles impede all investigators; others hinder investigators only in certain regions or institutions or are more relevant to specific types of immunotherapy or first-in-humans studies. Each of these hurdles can significantly delay clinical translation of promising advances in immunotherapy yet if overcome, have the potential to improve outcomes of patients with cancer. © 2011 Fox et al; licensee BioMed Central Ltd.

Published

2011

2. Role of circulating T follicular helper subsets following Ty21a immunization and oral challenge with wild type S . Typhi in humans.

Author

Booth JS, Rapaka RR, McArthur MA, Fresnay S, Darton TC, Blohmke CJ, Jones C, Waddington CS, Levine MM, Pollard AJ, and Sztein MB

Subjects

Humans, Male, Female, Adult, Antibodies, Bacterial blood, Antibodies, Bacterial immunology, Young Adult, Polysaccharides, Bacterial immunology, Immunization, Administration, Oral, Adolescent, Salmonella typhi immunology, Typhoid Fever immunology, Typhoid Fever prevention & control, Typhoid-Paratyphoid Vaccines immunology, Typhoid-Paratyphoid Vaccines administration & dosage, T Follicular Helper Cells immunology

Abstract

Despite decades of intense research, our understanding of the correlates of protection against Salmonella Typhi ( S . Typhi) infection and disease remains incomplete. T follicular helper cells (T FH ), an important link between cellular and humoral immunity, play an important role in the development and production of high affinity antibodies. While traditional T FH cells reside in germinal centers, circulating T FH (cT FH ) (a memory subset of T FH ) are present in blood. We used specimens from a typhoid controlled human infection model whereby participants were immunized with Ty21a live attenuated S . Typhi vaccine and then challenged with virulent S . Typhi. Some participants developed typhoid disease (TD) and some did not (NoTD), which allowed us to assess the association of cT FH subsets in the development and prevention of typhoid disease. Of note, the frequencies of cT FH were higher in NoTD than in TD participants, particularly 7 days after challenge. Furthermore, the frequencies of cT FH 2 and cT FH 17, but not cT FH 1 subsets were higher in NoTD than TD participants. However, we observed that ex-vivo expression of activation and homing markers were higher in TD than in NoTD participants, particularly after challenge. Moreover, cT FH subsets produced higher levels of S . Typhi-specific responses (cytokines/chemokines) in both the immunization and challenge phases. Interestingly, unsupervised analysis revealed unique clusters with distinct signatures for each cT FH subset that may play a role in either the development or prevention of typhoid disease. Importantly, we observed associations between frequencies of defined cT FH subsets and anti- S. Typhi antibodies. Taken together, our results suggest that circulating T FH 2 and T FH 17 subsets might play an important role in the development or prevention of typhoid disease. The contribution of these clusters was found to be distinct in the immunization and/or challenge phases. These results have important implications for vaccines aimed at inducing long-lived protective T cell and antibody responses., Competing Interests: ML: Co-inventor of a live attenuated S. Typhi vaccine strain CVD 909 and a S. Paratyphi A vaccine strain CVD 1902 that have been licensed to Bharat Biotech International BBI, Hyderabad, India for clinical development. ML is also a co-inventor of a Trivalent Salmonella Conjugate vaccine that includes S. Enteritidis, S. Typhimurium conjugates core plus O-polysaccharide covalently linked to FliC flagellin subunits of the homologous serovars in combination with BBI’s Vi conjugate Typbar TCV. AP: is chair of the UK department of Health and Social Cares Joint Committee on vaccination and immunisation. He has research grants on typhoid/paratyphoid vaccines from Serum Institute of India, Medical Research Council, Wellcome Trust and Bill & Melinda gates Foundation. Author MM was employed by company Sanofi. Authors SF and CB were employed by company GlaxsoSmithKline. Author RR is presently employed at Moderna Therapeutics and owns shares/options. Her contributions to this project were made prior to her employment at Moderna. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Booth, Rapaka, McArthur, Fresnay, Darton, Blohmke, Jones, Waddington, Levine, Pollard and Sztein.)

Published

2024

3. Role of cellular effectors in the induction and maintenance of IgA responses leading to protective immunity against enteric bacterial pathogens.

Author

Carreto-Binaghi LE, Sztein MB, and Booth JS

Subjects

Humans, Animals, Intestinal Mucosa immunology, Intestinal Mucosa microbiology, B-Lymphocytes immunology, Antibodies, Bacterial immunology, T-Lymphocytes immunology, Immunity, Innate, Immunoglobulin A immunology, Gastrointestinal Microbiome immunology, Immunity, Mucosal

Abstract

The mucosal immune system is a critical first line of defense to infectious diseases, as many pathogens enter the body through mucosal surfaces, disrupting the balanced interactions between mucosal cells, secretory molecules, and microbiota in this challenging microenvironment. The mucosal immune system comprises of a complex and integrated network that includes the gut-associated lymphoid tissues (GALT). One of its primary responses to microbes is the secretion of IgA, whose role in the mucosa is vital for preventing pathogen colonization, invasion and spread. The mechanisms involved in these key responses include neutralization of pathogens, immune exclusion, immune modulation, and cross-protection. The generation and maintenance of high affinity IgA responses require a delicate balance of multiple components, including B and T cell interactions, innate cells, the cytokine milieu (e.g., IL-21, IL-10, TGF-β), and other factors essential for intestinal homeostasis, including the gut microbiota. In this review, we will discuss the main cellular components (e.g., T cells, innate lymphoid cells, dendritic cells) in the gut microenvironment as mediators of important effector responses and as critical players in supporting B cells in eliciting and maintaining IgA production, particularly in the context of enteric infections and vaccination in humans. Understanding the mechanisms of humoral and cellular components in protection could guide and accelerate the development of more effective mucosal vaccines and therapeutic interventions to efficiently combat mucosal infections., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Carreto-Binaghi, Sztein and Booth.)

Published

2024

4. Integrating Multisector Molecular Characterization into Personalized Peptide Vaccine Design for Patients with Newly Diagnosed Glioblastoma.

Author

Johanns TM, Garfinkle EAR, Miller KE, Livingstone AJ, Roberts KF, Rao Venkata LP, Dowling JL, Chicoine MR, Dacey RG, Zipfel GJ, Kim AH, Mardis ER, and Dunn GP

Subjects

Humans, Female, Male, Middle Aged, Brain Neoplasms immunology, Brain Neoplasms therapy, Brain Neoplasms genetics, Brain Neoplasms pathology, Adult, Aged, Immunotherapy methods, Protein Subunit Vaccines, Glioblastoma immunology, Glioblastoma therapy, Glioblastoma genetics, Glioblastoma pathology, Cancer Vaccines immunology, Cancer Vaccines administration & dosage, Cancer Vaccines therapeutic use, Vaccines, Subunit immunology, Vaccines, Subunit administration & dosage, Vaccines, Subunit therapeutic use, Precision Medicine methods, Antigens, Neoplasm immunology

Abstract

Purpose: Outcomes for patients with glioblastoma (GBM) remain poor despite multimodality treatment with surgery, radiation, and chemotherapy. There are few immunotherapy options due to the lack of tumor immunogenicity. Several clinical trials have reported promising results with cancer vaccines. To date, studies have used data from a single tumor site to identify targetable antigens, but this approach limits the antigen pool and is antithetical to the heterogeneity of GBM. We have implemented multisector sequencing to increase the pool of neoantigens across the GBM genomic landscape that can be incorporated into personalized peptide vaccines called NeoVax., Patients and Methods: In this study, we report the findings of four patients enrolled onto the NeoVax clinical trial (NCT0342209)., Results: Immune reactivity to NeoVax neoantigens was assessed in peripheral blood mononuclear cells pre- and post-NeoVax for patients 1 to 3 using IFNγ-ELISPOT assay. A statistically significant increase in IFNγ producing T cells at the post-NeoVax time point for several neoantigens was observed. Furthermore, a post-NeoVax tumor biopsy was obtained from patient 3 and, upon evaluation, revealed evidence of infiltrating, clonally expanded T cells., Conclusions: Collectively, our findings suggest that NeoVax stimulated the expansion of neoantigen-specific effector T cells and provide encouraging results to aid in the development of future neoantigen vaccine-based clinical trials in patients with GBM. Herein, we demonstrate the feasibility of incorporating multisector sampling in cancer vaccine design and provide information on the clinical applicability of clonality, distribution, and immunogenicity of the neoantigen landscape in patients with GBM., (©2024 The Authors; Published by the American Association for Cancer Research.)

Published

2024

5. Glioblastoma-Infiltrating CD8+ T Cells Are Predominantly a Clonally Expanded GZMK+ Effector Population.

Author

Wang AZ, Mashimo BL, Schaettler MO, Sherpa ND, Leavitt LA, Livingstone AJ, Khan SM, Li M, Anzaldua-Campos MI, Bradley JD, Leuthardt EC, Kim AH, Dowling JL, Chicoine MR, Jones PS, Choi BD, Cahill DP, Carter BS, Petti AA, Johanns TM, and Dunn GP

Subjects

Humans, Lymphocytes, Tumor-Infiltrating immunology, Lymphocytes, Tumor-Infiltrating metabolism, Tumor Microenvironment immunology, Brain Neoplasms immunology, CD8-Positive T-Lymphocytes immunology, CD8-Positive T-Lymphocytes metabolism, Glioblastoma immunology, Glioblastoma therapy

Abstract

Recent clinical trials have highlighted the limited efficacy of T cell-based immunotherapy in patients with glioblastoma (GBM). To better understand the characteristics of tumor-infiltrating lymphocytes (TIL) in GBM, we performed cellular indexing of transcriptomes and epitopes by sequencing and single-cell RNA sequencing with paired V(D)J sequencing, respectively, on TILs from two cohorts of patients totaling 15 patients with high-grade glioma, including GBM or astrocytoma, IDH-mutant, grade 4 (G4A). Analysis of the CD8+ TIL landscape reveals an enrichment of clonally expanded GZMK+ effector T cells in the tumor compared with matched blood, which was validated at the protein level. Furthermore, integration with other cancer types highlights the lack of a canonically exhausted CD8+ T-cell population in GBM TIL. These data suggest that GZMK+ effector T cells represent an important T-cell subset within the GBM microenvironment and may harbor potential therapeutic implications., Significance: To understand the limited efficacy of immune-checkpoint blockade in GBM, we applied a multiomics approach to understand the TIL landscape. By highlighting the enrichment of GZMK+ effector T cells and the lack of exhausted T cells, we provide a new potential mechanism of resistance to immunotherapy in GBM. This article is featured in Selected Articles from This Issue, p. 897., (©2024 American Association for Cancer Research.)

Published

2024

6. Immunotherapy for Brain Tumors: Where We Have Been, and Where Do We Go From Here?

Author

Wang AF, Hsueh B, Choi BD, Gerstner ER, and Dunn GP

Subjects

Humans, Glioblastoma therapy, Glioblastoma immunology, Combined Modality Therapy methods, Treatment Outcome, Disease Management, Clinical Trials as Topic, Brain Neoplasms therapy, Brain Neoplasms immunology, Immunotherapy methods, Tumor Microenvironment immunology

Abstract

Opinion Statement: Immunotherapy for glioblastoma (GBM) remains an intensive area of investigation. Given the seismic impact of cancer immunotherapy across a range of malignancies, there is optimism that harnessing the power of immunity will influence GBM as well. However, despite several phase 3 studies, there are still no FDA-approved immunotherapies for GBM. Importantly, the field has learned a great deal from the randomized studies to date. Today, we are continuing to better understand the disease-specific features of the microenvironment in GBM-as well as the exploitable antigenic characteristic of the tumor cells themselves-that are informing the next generation of immune-based therapeutic strategies. The coming phase of next-generation immunotherapies is thus poised to bring us closer to treatments that will improve the lives of patients with GBM., (© 2024. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2024

7. Single-cell multi-omic analysis of the vestibular schwannoma ecosystem uncovers a nerve injury-like state.

Author

Barrett TF, Patel B, Khan SM, Mullins RDZ, Yim AKY, Pugazenthi S, Mahlokozera T, Zipfel GJ, Herzog JA, Chicoine MR, Wick CC, Durakovic N, Osbun JW, Shew M, Sweeney AD, Patel AJ, Buchman CA, Petti AA, Puram SV, and Kim AH

Subjects

Humans, Ecosystem, Multiomics, Schwann Cells metabolism, Signal Transduction physiology, Single-Cell Analysis, Tumor Microenvironment, Neuroma, Acoustic genetics, Neuroma, Acoustic metabolism, Neuroma, Acoustic pathology

Abstract

Vestibular schwannomas (VS) are benign tumors that lead to significant neurologic and otologic morbidity. How VS heterogeneity and the tumor microenvironment (TME) contribute to VS pathogenesis remains poorly understood. In this study, we perform scRNA-seq on 15 VS, with paired scATAC-seq (n = 6) and exome sequencing (n = 12). We identify diverse Schwann cell (SC), stromal, and immune populations in the VS TME and find that repair-like and MHC-II antigen-presenting SCs are associated with myeloid cell infiltrate, implicating a nerve injury-like process. Deconvolution analysis of RNA-expression data from 175 tumors reveals Injury-like tumors are associated with larger tumor size, and scATAC-seq identifies transcription factors associated with nerve repair SCs from Injury-like tumors. Ligand-receptor analysis and in vitro experiments suggest that Injury-like VS-SCs recruit myeloid cells via CSF1 signaling. Our study indicates that Injury-like SCs may cause tumor growth via myeloid cell recruitment and identifies molecular pathways that may be therapeutically targeted., (© 2023. The Author(s).)

Published

2024

8. Mesenchymal stem cell engineering by ARCA analog-capped mRNA.

Author

Andrzejewska A, Grzela R, Stankiewicz-Drogon A, Rogujski P, Nagaraj S, Darzynkiewicz E, Lukomska B, and Janowski M

Abstract

We previously have shown that mRNA-based engineering may enhance mesenchymal stem cell (MSC) trafficking. However, optimal conditions for in vitro mRNA engineering of MSCs are unknown. Here, we investigated several independent variables: (1) transfection factor (Lipofectamine 2000 vs. TransIT), (2) mRNA purification method (spin column vs. high-performance liquid chromatography [HPLC] column), and (3) mRNA capping (ARCA vs. β-S-ARCA D1 and β-S-ARCA D2). Dependent variables included protein production based on mRNA template (measured by the bioluminescence of reporter gene luciferase over hours), MSC metabolic activity corresponding with their wellbeing measured by CCK-8 over days, and endogenous expression of genes by RT-qPCR related to innate intracellular immune response and decapping at two time points: days 2 and 5. We have found that Lipofectamine 2000 outperforms TransIT, and used it throughout the study. Then, we showed that mRNA must be purified by HPLC to be relatively neutral to MSCs in terms of metabolic activity and endogenous protein production. Ultimately, we demonstrated that β-S-ARCA D1 enables higher protein production but at the cost of lower MSC metabolic activity, with no impact on RT-qPCR results. Thus Lipofectamine 2000-based in vitro transfection of HPLC-purified and ARCA- or β-S-ARCA D1-capped mRNA is optimal for MSC engineering., Competing Interests: M.J. is a co-founder of IntraART, Ti-com, and ART-EX, but they are not related to the current manuscript., (© 2023 The Authors.)

Published

2023

9. The legacy of mRNA engineering: A lineup of pioneers for the Nobel Prize.

Author

Janowski M and Andrzejewska A

Abstract

mRNA is like Hermes, delivering the genetic code to cellular construction sites, so it has long been of interest, but only to a small group of scientists, and only demonstrating its remarkable efficacy in coronavirus disease 2019 (COVID-19) vaccines allowed it to go out into the open. Therefore, now is the right timing to delve into the stepping stones that underpin this success and pay tribute to the underlying scientists. From this perspective, advances in mRNA engineering have proven crucial to the rapidly growing role of this molecule in healthcare. Development of consecutive generations of cap analogs, including anti-reverse cap analogs (ARCAs), has significantly boosted translation efficacy and maintained an enthusiasm for mRNA research. Nucleotide modification to protect mRNA molecules from the host's immune system, followed by finding appropriate purification and packaging methods, were other links in the chain enabling medical breakthroughs. Currently, vaccines are the central area of mRNA research, but it will reach far beyond COVID-19. Supplementation of missing or abnormal proteins is another large field of mRNA research. Ex vivo cell engineering and genome editing have been expanding recently. Thus, it is time to recognize mRNA pioneers while building upon their legacy., Competing Interests: M.J. is co-founder and co-owner of Ti-com, LLC and IntraART, LLC, but there is no direct relation of the manuscript’s content to the activity of either company., (© 2022 The Author(s).)

Published

2022

10. Mesenchymal stem cells in glioblastoma therapy and progression: How one cell does it all.

Author

Nowak B, Rogujski P, Janowski M, Lukomska B, and Andrzejewska A

Subjects

Animals, Brain Neoplasms metabolism, Brain Neoplasms therapy, Cell Movement, Cell Proliferation, Glioblastoma metabolism, Glioblastoma therapy, Humans, Mesenchymal Stem Cell Transplantation, Mesenchymal Stem Cells metabolism, Neoplasm Invasiveness, Tumor Microenvironment, Brain Neoplasms pathology, Cell Communication, Glioblastoma pathology, Mesenchymal Stem Cells pathology

Abstract

Mesenchymal stem cells (MSCs) are among the most investigated and applied somatic stem cells in experimental therapies for the regeneration of damaged tissues. Moreover, as it was recently postulated, MSCs may demonstrate anti-tumor properties. Glioblastoma (GBM) is a grade IV central nervous system tumor with no available effective therapy and an inevitably fatal prognosis. Experimental studies utilizing MSCs in GBM treatment resulted in numerous controversies. Native MSCs were shown to exert anti-GBM activity by controlling angiogenesis, regulating cell cycle, and inducing apoptosis. They also were used as sensitizing factors and vehicles delivering various anti-cancer compounds. On the other hand, some experiments revealed significant risks related to MSC-based therapies for GBM, such as enhancement of tumor cell proliferation, invasion, and aggressiveness. The following review elaborates on all mentioned contradictory data and provides a realistic, current clinical perspective on MSCs' potential in GBM treatment., (Copyright © 2021 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2021

11. Metabolic Codependencies in the Tumor Microenvironment.

Author

Dey P, Kimmelman AC, and DePinho RA

Subjects

Humans, Metabolic Networks and Pathways, Neoplasms pathology, Cell Transformation, Neoplastic, Neoplasms metabolism, Tumor Microenvironment

Abstract

Metabolic reprogramming enables cancer cell growth, proliferation, and survival. This reprogramming is driven by the combined actions of oncogenic alterations in cancer cells and host cell factors acting on cancer cells in the tumor microenvironment. Cancer cell-intrinsic mechanisms activate signal transduction components that either directly enhance metabolic enzyme activity or upregulate transcription factors that in turn increase expression of metabolic regulators. Extrinsic signaling mechanisms involve host-derived factors that further promote and amplify metabolic reprogramming in cancer cells. This review describes intrinsic and extrinsic mechanisms driving cancer metabolism in the tumor microenvironment and how such mechanisms may be targeted therapeutically. SIGNIFICANCE: Cancer cell metabolic reprogramming is a consequence of the converging signals originating from both intrinsic and extrinsic factors. Intrinsic signaling maintains the baseline metabolic state, whereas extrinsic signals fine-tune the metabolic processes based on the availability of metabolites and the requirements of the cells. Therefore, successful targeting of metabolic pathways will require a nuanced approach based on the cancer's genotype, tumor microenvironment composition, and tissue location., (©2021 American Association for Cancer Research.)

Published

2021

12. Mesenchymal Stem Cells for Neurological Disorders.

Author

Andrzejewska A, Dabrowska S, Lukomska B, and Janowski M

Subjects

Humans, Mesenchymal Stem Cell Transplantation methods, Nervous System Diseases therapy

Abstract

Neurological disorders are becoming a growing burden as society ages, and there is a compelling need to address this spiraling problem. Stem cell-based regenerative medicine is becoming an increasingly attractive approach to designing therapies for such disorders. The unique characteristics of mesenchymal stem cells (MSCs) make them among the most sought after cell sources. Researchers have extensively studied the modulatory properties of MSCs and their engineering, labeling, and delivery methods to the brain. The first part of this review provides an overview of studies on the application of MSCs to various neurological diseases, including stroke, traumatic brain injury, spinal cord injury, multiple sclerosis, amyotrophic lateral sclerosis, Alzheimer's disease, Huntington's disease, Parkinson's disease, and other less frequently studied clinical entities. In the second part, stem cell delivery to the brain is focused. This fundamental but still understudied problem needs to be overcome to apply stem cells to brain diseases successfully. Here the value of cell engineering is also emphasized to facilitate MSC diapedesis, migration, and homing to brain areas affected by the disease to implement precision medicine paradigms into stem cell-based therapies., Competing Interests: The authors declare no conflict of interest., (© 2021 The Authors. Advanced Science published by Wiley‐VCH GmbH.)

Published

2021

13. Mesenchymal stem cells injected into carotid artery to target focal brain injury home to perivascular space.

Author

Andrzejewska A, Dabrowska S, Nowak B, Walczak P, Lukomska B, and Janowski M

Subjects

Animals, Brain Injuries metabolism, Brain Injuries pathology, Cell Adhesion, Cells, Cultured, Disease Models, Animal, Male, Mesenchymal Stem Cells metabolism, Rats, Rats, Wistar, Transfection, Brain Injuries therapy, Carotid Arteries metabolism, Glymphatic System metabolism, Integrin alpha4beta1 metabolism, Mesenchymal Stem Cell Transplantation methods, Mesenchymal Stem Cells cytology, Vascular Cell Adhesion Molecule-1 metabolism

Abstract

Rationale : The groundbreaking discovery of mesenchymal stem cells (MSCs) with their multifaceted benefits led to their widespread application in experimental medicine, including neurology. Efficient delivery of MSCs to damaged regions of the central nervous system may be a critical factor in determining outcome. Integrin VLA-4 (α4β1) coded by ITGA4 and ITGB1 genes is an adhesion molecule expressed by leukocytes, which is responsible for initiation of their diapedesis through cell docking to the inflamed vessel wall expressing VCAM1 receptor. This function of VLA-4 has been recapitulated in neural stem cells and glial progenitors. Thus, it was prudent to investigate this tool as a vehicle driving extravasation of MSCs. Since MSCs naturally express ITGB1 subunit, we decided to supplement them with ITGA4 only. The purpose of our current study is to investigate the eventual fate of IA delivered ITGA4 engineered and naive MSCs. Methods : mRNA-ITGA4 transfected and naive MSCs were injected to right internal carotid artery of rats with focal brain injury. Through next three days MSC presence in animals' brain was navigated by magnetic resonance imaging. Transplanted cell location relative to the brain blood vessels and host immunological reaction were analyzed post-mortem by immunohistochemistry. The chemotaxis of modified and naive MSCs was additionally examined in in vitro transwell migration assay. Results : Both naïve and ITGA4-overexpressing cells remained inside the vascular lumen over the first two days after IA infusion. On the third day, 39% of mRNA-ITGA4 modified and 51% naïve MSCs homed to perivascular space in the injury region (p=NS). The gradual decrease of both naive and mRNA-ITGA4 transfected hBM-MSCs in the rat brain was observed. mRNA-ITGA4 transfected MSCs appeared to be more vulnerable to phagocytosis than naïve cells. Moreover, in vitro study revealed that homogenate from the injured brain repels migration of MSCs, corroborating the incomplete extravasation observed in vivo . Conclusions : In summary, IA transplanted MSCs are capable of homing to the perivascular space, an integral part of neurovascular unit, which might contribute to the replacement of injured pericytes, a critical element facilitating restoration of CNS function. The mRNA-ITGA4 transfection improves cell docking to vessel but this net benefit vanishes over the next two days due to fast clearance from cerebral vessels of the majority of transplanted cells, regardless of their engineering status. The drawbacks of mRNA-ITGA4 transfection become apparent on day 3 post transplantation due to the lower survival and higher vulnerability to host immune attack., Competing Interests: Competing Interests: The authors have declared that no competing interest exists., (© The author(s).)

Published

2020

14. PD-L1-Independent Mechanisms Control the Resistance of Melanoma to CD4 + T Cell Adoptive Immunotherapy.

Author

Goding SR, Wilson KA, Rosinsky C, and Antony PA

Subjects

Animals, Antigens, CD immunology, B7-H1 Antigen immunology, Mice, Mice, Transgenic, Lymphocyte Activation Gene 3 Protein, CD4-Positive T-Lymphocytes transplantation, Drug Resistance, Neoplasm immunology, Immunotherapy, Adoptive methods, Melanoma, Experimental immunology, Skin Neoplasms immunology

Abstract

Immunotherapy is becoming the standard of care for melanoma. However, resistance to therapy is a major problem. Previously, we showed that tumor-specific, cytotoxic CD4 + T cells from tyrosinase-related protein 1 transgenic mice could overcome secondary resistance to recurring melanoma when anti-programmed cell death 1 ligand (PD-L1) checkpoint blockade was combined with either anti-lymphocyte-activated gene 3 (LAG-3) Abs or depletion of tumor-specific regulatory T (T reg ) cells. In this study, we show that PD-L1 expressed by the host, not B16 melanoma, plays a major role in the early stages of exhaustion or primary resistance. We observed durable regression of melanoma in tumor-bearing PD-L1 -/- RAG -/- mice with transfer of naive tumor-specific CD4 + T cells. However, exhausted tumor-specific CD4 + T cells, which included tumor-specific T reg cells, failed to maintain durable regression of tumors in PD-L1 -/- RAG -/- mice unless tumor-specific T reg cells were eliminated, showing nonredundant pathways of resistance to immunotherapy were present. Translating these findings to a clinically relevant model of cancer immunotherapy, we unexpectedly showed that anti-PD-L1 checkpoint blockade mildly improved immunotherapy with tumor-specific CD4 + T cells and irradiation in wild-type mice. Instead, anti-LAG-3 checkpoint blockade, in combination with tumor-specific CD4 + T cells and irradiation, overcame primary resistance and treated established tumors resulting in fewer recurrences. Because LAG-3 negatively regulates effector T cell function and activates T reg cells, LAG-3 blockade may be more beneficial in overcoming primary resistance in combination immunotherapies using adoptive cellular therapy and irradiation than blockade of PD-L1., (Copyright © 2018 by The American Association of Immunologists, Inc.)

Published

2018

15. A role for pre-mNK cells in tumor progression.

Author

Rosinsky C and Antony PA

Abstract

The innate and adaptive immune systems have evolved together to fight infection and cancerous tissues. The innate immune system emerges first with the adaptive immune system following, both ostensibly being bridged by dendritic cells (DC). Recently cells have emerged that possess characteristics of both innate and adaptive immune cell qualities, termed interferon-producing killer dendritic cells (IKDCs). These cells have an indistinct origin that is not well understood. They appear to have more NK cell attributes than DC but purportedly can regulate the immune system similar to immunoregulatory NK cells. Because of this, they have been renamed pre-mNK cells (pre-mature NK cells). We argue in this commentary that pre-mNK cells may contribute to cancer recurrence.

Published

2016

16. Depletion of B220 + NK1.1 + cells enhances the rejection of established melanoma by tumor-specific CD4 + T cells.

Author

Wilson KA, Goding SR, Neely HR, Harris KM, and Antony PA

Abstract

Five-year survival rates for patients diagnosed with metastatic melanoma are less than 5%. Adoptive cell transfer (ACT) has achieved an objective response of 50% by Response Evaluation Criteria in Solid Tumors (RECIST) in this patient population. For ACT to be maximally effective, the host must first be lymphodepleted. It is hypothesized that lymphodepletion may remove regulatory elements and cytokine sinks, or increase the activation and availability of antigen presenting cells (APCs). We use an in vivo model to study the ACT of tumor-associated antigen (TAA)-specific CD4 + T cells (TRP-1 cells). We have discovered that depletion of NK1.1 + cells enhances the rejection of established melanoma tumors by adoptively transferred TRP-1 CD4 + T cells. NK1.1 + cell depletion increases the number of CD4 + T cells, the serum concentration of pro-inflammatory cytokines, autoimmune vitiligo, host survival and prevented recurrence after ACT. Because multiple cells express NK1.1, we targeted different NK1.1 + cell populations using antibodies specific for NK cells, pre-mNK cells, and innate lymphoid cells (ILCs). Our data suggests that NK1.1 + B220 + pre-mNK cells (also known as interferon-producing killer dendritic cells; IKDCs) are an important inhibitor of the CD4 + T cell response to melanoma. Understanding this mechanism may help design new immunotherapies to modulate the activity of pre-mNKs in the face of an antitumor immune response and inhibit their suppression of adoptively transferred T cells.

Published

2015

17. Augmentation of antitumor immune responses after adoptive transfer of bone marrow derived from donors immunized with tumor lysate-pulsed dendritic cells.

Author

Asavaroengchai W, Kotera Y, Koike N, Pilon-Thomas S, and Mulé JJ

Subjects

Animals, Antigens, CD analysis, Bone Marrow Cells cytology, Bone Marrow Cells immunology, Bone Marrow Transplantation methods, Coculture Techniques, Dendritic Cells transplantation, Female, Flow Cytometry, Genes, MHC Class I genetics, Genes, MHC Class I immunology, Immunophenotyping, Interferon-gamma metabolism, Lung Neoplasms immunology, Lung Neoplasms pathology, Lung Neoplasms secondary, Lymphocyte Activation immunology, Lymphocyte Depletion, Mammary Neoplasms, Experimental immunology, Mammary Neoplasms, Experimental pathology, Melanoma, Experimental immunology, Melanoma, Experimental pathology, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Mice, Knockout, T-Lymphocytes cytology, T-Lymphocytes immunology, T-Lymphocytes metabolism, Vaccination, Adoptive Transfer, Antigens, Neoplasm immunology, Bone Marrow Transplantation immunology, Dendritic Cells immunology

Abstract

We demonstrated previously that tumor lysate-pulsed dendritic cells (TP-DC) could mediate a specific and long-lasting antitumor immune response against a weakly immunogenic breast tumor during early lymphoid reconstitution. The purpose of this study was to examine the potential therapeutic efficacy of bone marrow transplants from TP-DC-vaccinated donors. In 2 aggressive metastatic models, bone marrow transplantation with donor bone marrow cells from TP-DC-immunized mice mediated a tumor-specific immune response in the recipient, and this caused regressions of preexisting tumor metastases. After vaccination with TP-DC, donors harbored increased numbers of both activated CD4+ and CD8+ T-cell populations in the bone marrow. Adoptive transfer of T cells purified from the bone marrow of TP-DC-vaccinated mice led to a reduction in preestablished lung metastases, whereas depletion of T cells from bone marrow abolished this effect. By using T cells derived from the bone marrow of TP-DC-vaccinated major histocompatibility complex class I and class II knockout mice, the effector cells required for the observed antitumor effect were determined to be major histocompatibility complex class I-restricted CD8+ T cells. Additionally, the tumor burden in TP-DC-immunized transplant recipients could be reduced further by repetitive TP-DC immunizations after bone marrow transplantation. Collectively, these results demonstrate an important therapeutic role of bone marrow from TP-DC-immunized donors and raise the potential for this approach in patients with advanced cancer.

Published

2004

18. Vaccination of pediatric solid tumor patients with tumor lysate-pulsed dendritic cells can expand specific T cells and mediate tumor regression.

Author

Geiger JD, Hutchinson RJ, Hohenkirk LF, McKenna EA, Yanik GA, Levine JE, Chang AE, Braun TM, and Mulé JJ

Subjects

Adolescent, Child, Child, Preschool, Female, Hemocyanins immunology, Humans, Hypersensitivity, Delayed immunology, Interferon-gamma metabolism, Leukapheresis, Male, T-Lymphocytes metabolism, Vaccination, Dendritic Cells immunology, Immunotherapy, Adoptive, Neoplasms immunology, Neoplasms therapy, T-Lymphocytes immunology

Abstract

Dendritic cells (DCs) have been shown to be a promising adjuvant for inducing immunity to cancer. We evaluated tumor lysate-pulsed DC in a Phase I trial of pediatric patients with solid tumors. Children with relapsed solid malignancies who had failed standard therapies were eligible. The vaccine used immature DC (CD14-, CD80+, CD86+, CD83-, and HLA-DR+) generated from peripheral blood monocytes in the presence of granulocyte/monocyte colony-stimulating factor and interleukin-4. These DC were then pulsed separately with tumor cell lysates and the immunogenic protein keyhole limpet hemocyanin (KLH) for 24 h and then combined. A total of 1 x 10(6) to 1 x 10(7) DC are administered intradermally every 2 weeks for a total of three vaccinations. Fifteen patients (ages 3-17 years) were enrolled with 10 patients completing all vaccinations. Leukapheresis yields averaged 2.8 x 10(8) peripheral blood mononuclear cells (PBMC)/kg, and DC yields averaged 10.9% of starting PBMC. Patients with neuroblastoma, sarcoma, and renal malignancies were treated without obvious toxicity. Delayed-type hypersensitivity (DTH) response was detected in 7 of 10 patients for KLH and 3 of 6 patients for tumor lysates. Priming of T cells to KLH was seen in 6 of 10 patients and to tumor in 3 of 7 patients as demonstrated by specific IFN-gamma-secreting T cells in unstimulated PBMCs. Significant regression of multiple metastatic sites was seen in 1 patient. Five patients showed stable disease, including 3 who had minimal disease at time of vaccine therapy and remain free of tumor with 16-30 months follow-up. Our results demonstrate that it is feasible to generate large numbers of functional DC from pediatric patients even in those highly pretreated and with a large tumor burden. The DC can be administered in an outpatient setting without any observable toxicity. Most importantly, we have demonstrated the ability of the tumor lysate/KLH-pulsed DC to generate specific T-cell responses and to elicit regression of metastatic disease.

Published

2001