Project description:Among the dendritic cell (DC) subsets, plasmacytoid DC’s are thought to be important in both generating antiviral and antitumor responses. These cells may be useful in developing dendritic cell-based tumor vaccines, however, the rarity of these cells in the peripheral blood have hampered attempts to understand their biology. To provide better insight into the biology of plasmacytoid DCs, we isolated these cells from the peripheral blood of healthy donors in order to further characterize their gene expression. Using gene array technology we compared the genetic profiles of these cells to those of CD14+ monocytes isolated from the same donors and found several immune related genes upregulated in this cell population. Understanding the genetic profiles of this dendritic cell subtype as well as others such as the BDCA-1 expressing myeloid DCs may enable us to manipulate these cells ex-vivo to generate enhanced DC-based tumor vaccines inducing more robust antitumor responses. Experiment Overall Design: 4 replicates of BDCA cells and CD14 cells

Project description:Dendritic cell (DC) vaccine was among the first FDA-approved cancer immunotherapies, but has been limited by the modest cytotoxic T lymphocyte (CTL) response and therapeutic efficacy. Here we report a facile metabolic labeling approach that enables targeted modulation of adoptively transferred DCs for developing enhanced DC vaccines. We show that metabolic glycan labeling can reduce the membrane mobility of DCs, which activates DCs and improves the antigen presentation and subsequent T cell priming property of DCs. Metabolic glycan labeling itself can enhance the antitumor efficacy of DC vaccines. In addition, the cell-surface chemical tags (e.g., azido groups) introduced via metabolic glycan labeling also enable in vivo conjugation of cytokines onto adoptively transferred DCs, which further enhances CTL response and antitumor efficacy. Our DC labeling and targeting technology provides a new strategy to improve the therapeutic efficacy of DC vaccines, with minimal interference upon the clinical manufacturing process.

Project description:Cancer vaccines utilizing naturally circulating dendritic cell (DC) subsets, such as plasmacutoid DCs (pDCs) and type 2 convential DCs (cDC2s), have demonstrated their potential as a therapy. For melanoma in recent clinical trials. These DC vaccines aim to. human. DC subsets on the. T cell transcriptional program, which. forms the. molecular. basis. of an. antitumor. T cell response, is. poorly understood. In. this study, we investigated the eraly gene expressionsignature of CD8+ T. cells following. stimulation by pDCs or cDC2s. in. a culture system that mimics. the. current protocol of primary DC-based cancer vaccines. Our results demonstrate that pDCs and cDC2s induce a remarkably similar transcriptomic profile in CD8_ T cells, which. is tailored for increased effector function, survival and sensitivity. towards secondary signals. Nonetheless, differences between pDC- and cDC2-induced T cell gene expression signatures encompass genes with a role in proliferation, cytolytic capacity and differentiation. Combining both DC subsets results in a T cell. transcriptomic program that. is very. similar to. the program induced by. pDCs alone. The results suggest that the. choice of DC subsets for use in cancer vaccines impacts the induced antitumor CD8+ T cell response.

Project description:Tumor-associated macrophages (TAMs) represent abundantly in the tumor microenvironment (TME) and are thought to be novel targets for cancer immunotherapy. To elucidate the antitumor effects of therapeutics targeting human TAMs in vivo, we have here established a preclinical tumor xenograft model using immunodeficient mice expressing multiple human cytokines (MITRG mice) and examined the anti-tumor effect of anti–human SIRPα antibodies SE12C3, which inhibit the interaction of CD47 on tumor cells and enhance Fcγ receptor-mediated phagocytosis of tumor cells by human macrophages. Humanized immune system (HIS)–MITRG mice particularly facilitate human macrophage differentiation following transplantation of human CD34+ hematopoietic stem and progenitor cells. HIS–MITRG mice promoted the growth of both cell line– and patient–derived B cell lymphoma and infiltration of human TAMs into the tumor. Treatment of rituximab with SE12C3 markedly inhibited B–cell lymphoma growth in HIS-MITRG mice. The inhibition of B–cell lymphoma growth depended on human macrophages and was attributable to the promotion of rituximab–mediated lymphoma cell phagocytosis by human macrophages. In addition, the treatment of rituximab with SE12C3 induced reprogramming of human TAMs towards the pro-inflammatory phenotype in the TME. Furthermore, we demonstrated that the treatment of rituximab with SE12C3 significantly inhibited diffuse large B–cell lymphoma patient–derived tumor growth in HIS–MITRG mice. Together, HIS–MITRG mice provide an excellent mouse model for in vivo preclinical evaluation of the anti-tumor effect of therapeutics targeting human TAMs in the TME, such as anti–human SIRPα antibodies.

Project description:A novel affinity-tuned dual-checkpoint bispecific antibody with potent PD-L1 and moderate CD47 affinity was designed to improve the selectivity to TME and thus enhance antitumor immunity and efficacy. The scRNAseq analysis was performed to examine the immune cell modulation in TME following the CD47/PD-L1 bispecific treatment.

Project description:A membrane protein SIRPα (CD172a) interacts with another membrane protein CD47 and thereby constitutes a cell–cell contact signal. To investigate the functional role of CD47-SIRPα signal in the brain, we analyzed the effect of genetic ablation of CD47-SIRPα signal on the gene expression profile in specific brain cells by the use of microarrays.

Project description:A membrane protein SIRPα (CD172a) interacts with another membrane protein CD47 and thereby constitutes a cell–cell contact signal. To investigate the functional role of CD47-SIRPα signal in the brain, we analyzed the effect of genetic ablation of CD47-SIRPα signal on the gene expression profile in specific brain regions by the use of microarrays.

Project description:A novel affinity-tuned dual-checkpoint bispecific antibody with potent PD-L1 and moderate CD47 affinity was designed to improve the selectivity to TME and thus enhance antitumor immunity and efficacy. The gene expression analysis using Nanostring platform was performed to examine the immune cell modulation in TME following the CD47/PD-L1 bispecific treatment.

Project description:CD47 is a transmembrane glycoprotein that is ubiquitously expressed in different organs and tissues (Barclay and Van den Berg 2014; Liu, et al. 2017). In the human immune system, CD47 interacts with some integrins, two counter-receptor signal regulator protein (SIRP) family members, and the secreted thrombospondin-1 (TSP1) (Barclay and Van den Berg 2014; Gao, et al. 2016; Kaur, et al. 2013; Oldenborg, et al. 2000). CD47 has two established roles in the immune system. The CD47-SIRPα interaction was identified as a critical innate immune checkpoint, which delivers an antiphagocytic signal to macrophages and inhibits neutrophil cytotoxicity (Martínez- Sanz, et al. 2021). Its interaction with inhibitory SIRPα is a physiological anti-phagocytic “don’t eat me” signal on circulating red blood cells that is co-opted by cancer cells (Matlung, et al. 2017). Many malignant cells overexpress CD47 (Betancur, et al. 2017; Chao, et al. 2011; Jaiswal, et al. 2009; Majeti, et al. 2009; Oronsky, et al. 2020; Petrova, et al. 2017). CD47/SIRPα-targeted therapeutics have been developed to overcome this immune checkpoint for cancer treatment (Kaur, et al. 2020; Matlung, et al. 2017). Secondly, engagement of CD47 on T cells by TSP1 regulates their differentiation and survival (Grimbert, et al. 2006; Lamy, et al. 2007) and inhibits T cell receptor signaling and antigen presentation by dendritic cells (DCs) (Kaur, et al. 2014; Li, et al. 2002; Liu, et al. 2015; Miller, et al. 2013; Soto-Pantoja, et al. 2014; Weng, et al. 2014). TSP1/CD47 signaling has similar inhibitory functions to limit NK cell activation (Kim, et al. 2008; Nath, et al. 2018; Nath, et al. 2019; Schwartz, et al. 2019) and IL1β production by macrophages (Stein, et al. 2016). CD47 is therefore a checkpoint that regulates both innate and adaptive immunity. The recent understanding of CD47 antagonism associated with increased antigen presentation by DCs (Liu, et al. 2016) and natural killer cell cytotoxicity (Nath, et al. 2019) contributes to the heightened interest in CD47 as a therapeutic target (Kaur, et al. 2020).

Project description:CD47 is the only 5-transmembrane (5-TM) spanning receptor of the immune system. Its extracellular domain (ECD) is a cell surface ‘marker of self’ that binds SIRPα and inhibits macrophage phagocytosis, and cancer immuno-therapy approaches in clinical trials are focused on blocking CD47/SIRPα interaction. Using hydrogen-deuterium exchange we show that CD47’s ECLR architecture, comprised of two extracellular loops and the SWF loop, creates a molecular environment stabilizing the ECD for presentation on the cell surface.