Suppressor of T-cell receptor signalling 1 and 2 (Sts-1 and 2) negatively regulate the endocytosis of receptor tyrosine kinases. The UBA domain of Sts-2 and SH3-dependent Cbl-binding are required for this function. Sts-1 and -2 also possess a PGM domain, which was recently reported to exhibit tyrosine phosphatase activity. Here, we demonstrate that the PGM of Sts-1, but not of Sts-2, dephosphorylates the EGFR at multiple tyrosines thereby terminating its signalling and endocytosis. In contrast to Sts-2 the UBA of Sts-1 did not contribute significantly to receptor stabilization. Thus, although Sts-1 and Sts-2 are structurally highly homologous and both inhibit ligand-induced EGFR degradation, their mechanisms of action differ significantly. As a consequence, Sts-1-containing receptor complexes are inactive, whereas Sts-2-containing complexes are signalling competent.
Highlights d Engineered arenaviruses induce potent tumor self-specific CD8 T cell (CTL) response d Combinations of distantly but not closely related arenavirus vectors eliminate tumors d Vector backbone-targeted CTL responses compete against tumor self-reactive CTLs
Hepatocellular carcinoma (HCC) is a leading cause of cancer deaths, but its molecular heterogeneity hampers the design of targeted therapies. Currently, the only therapeutic option for advanced HCC is Sorafenib, an inhibitor whose targets include RAF. Unexpectedly, RAF1 expression is reduced in human HCC samples. Modelling RAF1 downregulation by RNAi increases the proliferation of human HCC lines in xenografts and in culture; furthermore, RAF1 ablation promotes chemical hepatocarcinogenesis and the proliferation of cultured (pre)malignant mouse hepatocytes. The phenotypes depend on increased YAP1 expression and STAT3 activation, observed in cultured RAF1-deficient cells, in HCC xenografts, and in autochthonous liver tumours. Thus RAF1, although essential for the development of skin and lung tumours, is a negative regulator of hepatocarcinogenesis. This unexpected finding highlights the contribution of the cellular/tissue environment in determining the function of a protein, and underscores the importance of understanding the molecular context of a disease to inform therapy design.
Infection with human papillomavirus (HPV) is associated with a variety of cancer types and limited therapy options. Therapeutic cancer vaccines targeting the HPV16 oncoproteins E6 and E7 have recently been extensively explored as a promising immunotherapy approach to drive durable antitumor T cell immunity and induce effective tumor control. With the goal to achieve potent and lasting antitumor T cell responses, we generated a novel lymphocytic choriomeningitis virus (LCMV)-based vaccine, TT1-E7E6, targeting HPV16 E6 and E7. This replication-competent vector was stably attenuated using a three-segmented viral genome packaging strategy. Compared to wild-type LCMV, TT1-E7E6 demonstrated significantly reduced viremia and CNS immunopathology. Intravenous vaccination of mice with TT1-E7E6 induced robust expansion of HPV16specific CD8 + T cells producing IFN-γ, TNF-α and IL-2. In the HPV16 E6 and E7-expressing TC-1 tumor model, mice immunized with TT1-E7E6 showed significantly delayed tumor growth or complete tumor clearance accompanied with prolonged survival. Tumor control by TT1-E7E6 was also achieved in established largesized tumors in this model. Furthermore, a combination of TT1-E7E6 with anti-PD-1 therapy led to enhanced antitumor efficacy with complete tumor regression in the majority of tumor-bearing mice that were resistant to anti-PD-1 treatment alone. TT1-E7E6 vector itself did not exhibit oncolytic properties in TC-1 cells, while the antitumor effect was associated with the accumulation of HPV16-specific CD8 + T cells with reduced PD-1 expression in the tumor tissues. Together, our results suggest that TT1-E7E6 is a promising therapeutic vaccine for HPV-positive cancers.
The RAS pathway is central to epidermal homeostasis, and its activation in tumors or in Rasopathies correlates with hyperproliferation. Downstream of RAS, RAF kinases are actionable targets regulating keratinocyte turnover; however, chemical RAF inhibitors paradoxically activate the pathway, promoting epidermal proliferation. We generated mice with compound epidermis-restricted BRAF/RAF1 ablation. In these animals, transient barrier defects and production of chemokines and Th2-type cytokines by keratinocytes cause a disease akin to human atopic dermatitis, characterized by IgE responses and local and systemic inflammation. Mechanistically, BRAF and RAF1 operate independently to balance MAPK signaling: BRAF promotes ERK activation, while RAF1 dims stress kinase activation. In vivo, JNK inhibition prevents disease onset, while MEK/ERK inhibition in mice lacking epidermal RAF1 phenocopies it. These results support a primary role of keratinocytes in the pathogenesis of atopic dermatitis, and the animals lacking BRAF and RAF1 in the epidermis represent a useful model for this disease.DOI: http://dx.doi.org/10.7554/eLife.14012.001
Engineered viral vectors represent a promising strategy to trigger antigen-specific antitumor T cell responses. Arenaviruses have been widely studied because of their ability to elicit potent and protective T cell responses. Here, we provide an overview of a novel intravenously administered, replication-competent, non-lytic arenavirus-based vector technology that delivers tumor antigens to induce antigen-specific anti-cancer T cell responses. Preclinical studies in mice and cell culture experiments with human peripheral blood mononuclear cells demonstrate that arenavirus vectors preferentially infect antigen-presenting cells. This, in conjunction with a non-lytic functional activation of the infected antigen-presenting cells, leads to a robust antigen-specific CD8+ T cell response. T cell migration to, and infiltration of, the tumor microenvironment has been demonstrated in various preclinical tumor models with vectors encoding self- and non–self-antigens. The available data also suggest that arenavirus–based vector therapy can induce immunological memory protecting from tumor rechallenge. Based on promising preclinical data, a phase 1/2 clinical trial was initiated and is currently ongoing to test the activity and safety of arenavirus vectors, HB-201 and HB-202, created using lymphocytic choriomeningitis virus and Pichinde virus, respectively. Both vectors have been engineered to deliver non-oncogenic versions of the human papilloma virus 16 (HPV16) antigens E7 and E6 and will be injected intravenously with or without an initial intratumoral dose. This dose escalation/expansion study is being conducted in patients with recurrent or metastatic HPV16+ cancers. Promising preliminary data from this ongoing clinical study have been reported. Immunogenicity data from several patients demonstrate that a single injection of HB-201 or HB-202 monotherapy is highly immunogenic, as evidenced by an increase in inflammatory cytokines/chemokines and the expansion of antigen-specific CD8+ T cell responses. This response can be further enhanced by alternating injections of HB-202 and HB-201, which has resulted in frequencies of circulating HPV16 E7/E6-specific CD8+ T cells of up to 40% of the total CD8+ T cell compartment in peripheral blood in analyses to date. Treatment with intravenous administration also resulted in a disease control rate of 73% among 11 evaluable patients with head and neck cancer dosed every three weeks, including 2 patients with a partial response.
The unprecedented success of checkpoint blockade therapies clearly demonstrates the power of the immune system to fight cancer. Yet, only a minority of cancer patients respond with long-term control of the tumor or even cure, necessitating the development of other treatment modalities. Hookipa Pharma developed a novel attenuated, replication-competent viral vector platform (TheraT) that induces powerful cytotoxic T lymphocyte responses against foreign and self-antigens. In a preclinical model for human papilloma virus 16 (HPV16) associated cancer (TC-1), we evaluated immunogenicity and efficacy upon systemic and intratumoral application of TheraT vectors based on the arenaviruses lymphocytic choriomeningitis virus (LCMV) and pichinde virus (PICV). Both HB-201 (LCMV) and HB-202 (PICV) product candidates encode a non-oncogenic but highly antigenic E6/E7 fusion protein from HPV16. Independent of the route of administration, single administration of HB-201 or HB-202 induced potent peripheral E7-specific CD8+ T cell responses and led to efficient tumor growth control. Survival of TheraT treated animals was significantly longer compared to buffer treated animals. Similarly, single systemic as well as intratumoral application of HB-201 or HB-202 induced major infiltration of CD8+ T cells into the tumor microenvironment. Combination of intravenous HB-201 and anti-PD1 was well tolerated but did not further enhance efficacy in this model, implicating the presence of other immune evasion factors. In conclusion, replication-attenuated TheraT is safe, highly immunogenic and shows excellent therapeutic efficacy after single intravenous and intratumoral application. These data underline the potential and versatility of this novel vector platform. Mechanistic studies in various mouse tumor models are underway. Phase 1/2 clinical trial initiation of HB-201 monotherapy is planned for end of 2019 and preparations for an IND filing for a combination trial of HB-201 and HB-202 in H1 2020 have been initiated. Citation Format: Josipa Raguz, Sarah Schmidt, Theresa Kleisner, Manuel Zerbs, Goran Bekic, Sonja Feher, Daniel Oeler, Felix Stemeseder, Ursula Berka, Bettina Kiefmann, Sophie Schulha, Igor Matushansky, Henning Lauterbach, Klaus Orlinger. TheraT - a highly versatile arenavirus based vector platform for intravenous and intratumoral cancer immunotherapy [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 4058.
e14297 Background: The induction of powerful CD8+ T cell immunity to tumor associated self-antigens (TAAs) represents a critical yet challenging goal. Here we report on the development of an arenavirus-based delivery platform meeting this challenge. Previously we have shown that genetically engineered replication-attenuated lymphocytic choriomeningitis virus (LCMV) vectors, TheraT(LCMV), induce strong TAA-specific CD8 T cell immunity, but these responses can not be substantially augmented upon TheraT(LCMV) readministration. Counter to expectations, vector-neutralizing antibodies were not accountable for limited homologous prime-boosting capacity. Instead, dominant viral backbone-reactive CD8+ T cells competed against subdominant TAA-specific responses, limiting their magnitude. Methods: Herein we engineered and characterized delivery systems based on the arenaviruses Mopeia, Candid#1 and Pichinde (TheraT(MOP), TheraT(CAND), TheraT(PIC)). Results: We demonstrate that heterologous TheraT(CAND) – TheraT(LCMV) and TheraT(PIC)-TheraT(LCMV) prime-boost substantially augment TAA-specific CD8 T cell responses by rendering them immunodominant. Accordingly, intravenous administration of mice triggered up to 50% TAA epitope-specific CD8+ T cells and cured established tumors. Conversely, TheraT(MOP) – TheraT(LCMV) prime-boost was poorly immunogenic owing to cross-reactive T cell epitopes in the respective viral backbones. Conclusions: These findings establish heterologous arenavirus prime-boost combinations as a powerful new modality in tumor immunotherapy and highlight CD8 T cell epitope dominance as a significant hurdle to overcome in the vectored delivery of TAAs.
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