Lymphoid organs, in which antigen presenting cells (APCs) are in close proximity to T cells, are the ideal microenvironment for efficient priming and amplification of T-cell responses. However, the systemic delivery of vaccine antigens into dendritic cells (DCs) is hampered by various technical challenges. Here we show that DCs can be targeted precisely and effectively in vivo using intravenously administered RNA-lipoplexes (RNA-LPX) based on well-known lipid carriers by optimally adjusting net charge, without the need for functionalization of particles with molecular ligands. The LPX protects RNA from extracellular ribonucleases and mediates its efficient uptake and expression of the encoded antigen by DC populations and macrophages in various lymphoid compartments. RNA-LPX triggers interferon-α (IFNα) release by plasmacytoid DCs and macrophages. Consequently, DC maturation in situ and inflammatory immune mechanisms reminiscent of those in the early systemic phase of viral infection are activated. We show that RNA-LPX encoding viral or mutant neo-antigens or endogenous self-antigens induce strong effector and memory T-cell responses, and mediate potent IFNα-dependent rejection of progressive tumours. A phase I dose-escalation trial testing RNA-LPX that encode shared tumour antigens is ongoing. In the first three melanoma patients treated at a low-dose level, IFNα and strong antigen-specific T-cell responses were induced, supporting the identified mode of action and potency. As any polypeptide-based antigen can be encoded as RNA, RNA-LPX represent a universally applicable vaccine class for systemic DC targeting and synchronized induction of both highly potent adaptive as well as type-I-IFN-mediated innate immune mechanisms for cancer immunotherapy.
Targeting mRNA to eukaryotic cells is an emerging technology for basic research and provides broad applications in cancer immunotherapy, vaccine development, protein replacement, and in vivo genome editing. Although a plethora of nanoparticles for efficient mRNA delivery exists, in vivo mRNA targeting to specific organs, tissue compartments, and cells remains a major challenge. For this reason, methods for reporting the in vivo targeting specificity of different mRNA nanoparticle formats will be crucial. Here, we describe a straightforward method for monitoring the in vivo targeting efficiency of mRNA-loaded nanoparticles in mice. To achieve accurate mRNA delivery readouts, we loaded lipoplex nanoparticles with Cre-recombinase-encoding mRNA and injected these into commonly used Cre reporter mouse strains. Our results show that this approach provides readouts that accurately report the targeting efficacy of mRNA into organs, tissue structures, and single cells as a function of the used mRNA delivery system. The method described here establishes a versatile basis for determining in vivo mRNA targeting profiles and can be systematically applied for testing and improving mRNA packaging formats.
Immunotherapeutic approaches have evolved as promising and valid alternatives to available conventional cancer treatments. Amongst others, vaccination with tumor antigen-encoding RNAs by local administration is currently successfully employed in various clinical trials. To allow for a more efficient targeting of antigen-presenting cells (APCs) and to overcome potential technical challenges associated with local administration, we have developed a novel RNA immunotherapeutic for systemic application based on a fixed set of four liposome complexed RNA drug products (RNA(LIP)), each encoding one shared melanoma-associated antigen. The novel RNA(LIP) formulation was engineered (i) to protect RNA from degradation by plasma RNases and (ii) to enable directed in vivo targeting of APCs in lymphoid compartments, thus (iii) allowing for intravenous administration of multiple RNA products advancing from local to systemic targeting of APCs. Here, RNA(LIP) products trigger a Toll-like receptor (TLR)-mediated Interferon-α (IFN-α) release from plasmacytoid dendritic cells (DCs) and macrophages stimulating DC maturation and hence inducing innate immune mechanisms as well as potent vaccine antigen-specific immune responses. Notably, BioNTech RNA Pharmaceuticals′ RNA(LIP) formulation is a universally applicable potent novel vaccine class for intravenous APC targeting and the induction of potent synchronized adaptive and type-I interferon-mediated innate immune responses for cancer immunotherapy. Similar to other liposomal drugs, the ready-to-use RNA(LIP) products are prepared individually in a straight-forward manner directly prior to use from three components, namely solutions containing RNA drug product, NaCl diluent, and liposome excipient, that are provided as a kit. A multi-center phase I/II trial to clinically validate this pioneering RNA(LIP) formulation for the treatment of malignant melanoma was initiated in 2015 (NCT02410733). The objective of the clinical trial is to study the feasibility, safety, tolerability, immunogenicity and evaluate potential clinical activity of the RNA(LIP) immunotherapy concept. Detailed information on the ongoing trial, the recruitment and treatment status as well as data on the assessment of vaccine-induced immune responses will be presented. Citation Format: Robert A. Jabulowsky, Carmen Loquai, Mustafa Diken, Lena M. Kranz, Heinrich Haas, Sebastian Attig, Nicole Bidmon, Janina Buck, Evelyna Derhovanessian, Jan Diekmann, Daniel Fritz, Veronika Jahndel, Alexandra Kemmer-Brueck, Klaus Kuehlcke, Andreas N. Kuhn, Peter Langguth, Ulrich Luxemburger, Martin Meng, Felicitas Mueller, Richard Rae, Fatih Sari, Doreen Schwarck-Kokarakis, Christine Seck, Kristina Spieß, Meike Witt, Jessica C. Hassel, Jochen Utikal, Roland Kaufmann, Sebastian Kreiter, Christoph Huber, Oezlem Tuereci, Ugur Sahin. A first-in-human phase I/II clinical trial assessing novel mRNA-lipoplex nanoparticles for potent cancer immunotherapy in patients with malignant melanoma. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr CT032.
Mechanisms of antiviral host defense are important for survival and evolutionarily optimized for high sensitivity and potency. Intending to harvest the multitude of highly specialized and intertwined pathogen immune defense programs for cancer immunotherapy, we simulated a systemic pathogen intrusion into the blood stream by intravenous injection of lipid-formulated, tumor antigen-encoding mRNA nanoparticles. These RNA-lipoplexes (RNA-LPX) were directed to various lymphoid tissues, including the spleen, lymph nodes and bone marrow, which provide the ideal microenvironment for efficient priming and amplification of T cell responses. Solely the RNA-to-lipid ratio was discovered to determine the biodistribution of RNA-LPX, irrespective of the types of lipids used, and a slightly negative particle net charge was able to specifically transfect lymphoid-resident antigen presenting cells (APCs). Following uptake by CD11c+ DCs, pDCs and macrophages in the marginal zone of the spleen and in other lymphoid organs, predominantly by macropinocytosis, RNA recognition via TLR7 triggered two transient waves of type I IFN production by pDCs (early response) and macrophages (delayed response), which established an inflammatory, lymphocyte-activating milieu reminiscent of that initiated during the early systemic phase of viral infection. These IFNα receptor (IFNAR)-dependent immune mechanisms were required for DCs to mature, migrate into the T cell zones and express RNA-encoded tumor antigens. Presentation on MHC class I and II in the context of upregulated CD40, CD69 and CD86 elicited strong effector and memory CD8 and CD4 T cell immunity against viral, mutant neo-antigens or self-antigens, which was able to reject progressive tumors in therapeutic mouse models of melanoma, colon carcinoma and human papilloma virus (HPV)-associated cancer. In an ongoing phase I dose escalation study, the first cohort of three patients with advanced melanoma received RNA-LPX encoding four shared tumor antigens at doses lower than those used in the mouse studies. All patients showed a dose-dependent IFNα- and IP-10-dominated cytokine response, developed de novo CD4 and CD8 T cell responses or enhanced pre-existing immunity against the encoded self-antigens NY-ESO-I, Tyrosinase and MAGE-A3, and have stable disease to date. These results support the preclinically identified mode of action and strong potency of this approach in the clinical setting. Our study presents a novel class of systemically administered nanoparticulate RNA vaccines acting by body-wide delivery of encoded antigens to APCs and simultaneous initiation of a strong type I IFN-driven immunostimulatory program. Precise DC targeting in lymphoid compartments is accomplished using well-known lipid carriers and only by manipulating the net charge of the nanoparticles. RNA-LPX vaccines appear to mimic infectious non-self and thus mobilize both adaptive and innate immune mechanisms, connecting effective cancer immunotherapy with host pathogen-defense mechanisms. The simple but highly versatile design allows vaccine preparation with any type of RNA-encoded antigen and may thus be regarded as a universally applicable, first-in-class vaccine platform for cancer immunotherapy. Citation Format: Lena M. Kranz, Mustafa Diken, Heinrich Haas, Sebastian Kreiter, Carmen Loquai, Kerstin C. Reuter, Martin Meng, Daniel Fritz, Fulvia Vascotto, Hossam Hefesha, Christian Grunwitz, Mathias Vormehr, Yves Hüsemann, Abderraouf Selmi, Andreas N. Kuhn, Janina Buck, Evelyna Derhovanessian, Richard Rae, Sebastian Attig, Jan Diekmann, Robert A. Jabulowsky, Sandra Heesch, Jessica Hassel, Peter Langguth, Stephan Grabbe, Christoph Huber, Özlem Türeci, Ugur Sahin. Systemic RNA vaccines: Connecting effective cancer immunotherapy with antiviral defense mechanisms [abstract]. In: Proceedings of the Second CRI-CIMT-EATI-AACR International Cancer Immunotherapy Conference: Translating Science into Survival; 2016 Sept 25-28; New York, NY. Philadelphia (PA): AACR; Cancer Immunol Res 2016;4(11 Suppl):Abstract nr A004.
TPS2669 Background: Drugs targeting pathogen associated molecular patterns are an attractive strategy to stimulate the immune system. Toll-like receptors (TLR) have generated significant interest as an effective means of stimulating the immune system that result in the killing of tumor cells. TLR-9 agonists can function to promote an early immune response and are an appealing partner for combination with checkpoint blockade to improve immune activation. Lefitolimod (MGN1703) is a covalently closed dumbbell-shaped DNA molecule that functions as a TLR-9 agonist. We developed a clinical trial combining lefitolimod with ipilimumab (anti-CTLA4) in patients with advanced malignancies. In the dose-escalation phase 19 patients were enrolled and no DLTs were encountered. Safety data and maximum planned dose level of lefitolimod at 120mg weekly and ipilimumab 3mg/kg every 3 weeks was previously presented. Adverse events related to the combination included fatigue, appetite loss, rash, and anemia. Methods: This trial (NCT02668770) was designed to evaluate the safety profile and maximum tolerated dose of lefitolimod with ipilimumab. A 3+3 trial design was used to establish safety of the combination at each dose level and guide the decision to escalate dose. Lefitolimod is administered via subcutaneous (SC) injection weekly while ipilimumab is given at 3mg/kg intravenous on day 8 of each 3 week cycle. Lefitolimod starting dose was 15mg SC weekly with 3 dose level escalations up to 120mg SC weekly. Patients receive treatment for 4 cycles (total 12 weeks) with the combination, and those with stable disease or response were eligible to remain on lefitolimod therapy for up to 1 year. Eligible patients have a metastatic or unresectable solid tumor refractory to standard therapies, ECOG ≤ 2, and normal organ and bone marrow function. Patients are allowed to have received prior checkpoint blockade agents. Enrollment in expansion cohorts in ongoing. To better understand relevant immunologic changes associated with treatment, paired pre- and post-treatment biopsies of target lesions and peripheral blood collection during treatment is required for target expansion cohort patient populations. In addition to evaluating target patient populations at the combination dose established during escalation, an expansion cohort for patients with cutaneous metastases involves combination treatment with intratumoral delivery of lefitolimod. Clinical trial information: NCT02668770.
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