A Comprehensive Experimental Guide to Studying Cross-Presentation in Dendritic Cells In Vitro.

Immunotherapy has revolutionized cancer treatment showing unprecedented long-term antitumor responses. However, most patients do not respond to immunotherapies due at least partly to immune suppression. Immunotherapy non-responders have high levels of circulating myeloid-derived suppressor cells (MDSCs)- an immunosuppressive innate cell population that suppresses both innate and adaptive immunity. Triple negative breast cancer (TNBC) is the most aggressive subtype of breast cancers with poor responses to conventional therapies. TNBC patients harbor higher levels of MDSC populations compared to non-TNBC breast cancer patients. Consequently, TNBC and other solid tumor patients who have high levels of circulating MDSCs respond poorly to immunotherapy. On the other hand, cross-presenting dendritic cells (DCs) are essential to generate an antitumor immune response. Breast cancer patients who harbor higher numbers of these DCs have a better prognosis than patients with lower DC numbers. Several strategies aiming at achieving an effective combination with immunotherapy are under active investigation. The central dogma of these strategies consists of inducing T cells into “immunologically cold tumors” which are defined by having low neoantigen burden and a paucity of T cells and DCs. Hence, strategies that enhance cross-presenting DCs and T cell antitumor potential while altering MDSC’s suppressive function are likely to be effectively combined with immunotherapy for a maximum therapeutic benefit. Protein Kinase C (PKC) is a family of enzymes that play a critical role in cell signaling controlling the balance between survival and cell death. With the discovery in 1980s that PKC is a receptor for the tumor-promoting phorbol esters, the dogma that PKC is an oncoprotein was fueled. This led to more than three decades of failed clinical trials trying to inhibit PKC in cancer. Recent evidence suggests that PKC isozymes are generally inactivated in cancer and that most mutations affecting PKC isozymes are in fact loss of function mutations. This suggests that PKC is a tumor suppressor rather than an oncoprotein and that strategies in cancer treatment should focus on restoring PKC, rather than inhibiting it. To date, the role of PKC isozymes in antitumor immunity is unknown. Herein, our novel data suggest that PKC agonism using established agonists reduced MDSC generation from bone marrow (BM) progenitors specifically via activation of the PKC delta (PKCδ) isoform. PKC agonism induced MDSC differentiation to cross-presenting CD103+ DCs both ex-vivo and in vivo. Additionally, PKC agonist-treated purified MDSCs lost their suppressive capacity on CD8+ T cells in both in vitro and in vivo suppression assays. In contrast, PKC agonism significantly increased the generation of cross-presenting DCs (cDC1) from BM progenitors. Treatment of TNBC-bearing C57BL/6J mice with PKC agonist PEP005 markedly reduced tumor burden by decreasing the frequencies of M-MDSCs in tumor, spleen, and bone marrow while increasing cDC1 frequencies in tumor and spleen. These findings propose PKC as a common pathway in myeloid cells to tip the balance from immune suppression to effective antitumor immunity. Citation Format: Mehdi Chaib, Jeremiah Holt, Laura Sipe, Ajeeth Pingili, Deidre Daria, Liza Makowski. Pkc agonism restricts immune suppression and promotes antigen cross-presentation in triple negative breast cancer [abstract]. In: Proceedings of the 2020 San Antonio Breast Cancer Virtual Symposium; 2020 Dec 8-11; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2021;81(4 Suppl):Abstract nr PS17-46.

Stroma-dependent development of two dendritic-like cell types with distinct antigen presenting capability

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Myeloid and plasmacytoid dendritic cells in induced sputum after allergen inhalation in subjects with asthma

Selective 5-Lipoxygenase Expression in Langerhans Cells and Impaired Dendritic Cell Migration in 5-LO-Deficient Mice Reveal Leukotriene Action in Skin

Dendritic cells (DC) have the unique ability to present exogenous antigens via the major histocompatibility complex class I pathway to stimulate naive CD8+ T cells. In DCs with a non-functional mutation in Unc93b1 (3d mutation), endosomal acidification, phagosomal maturation, antigen degradation, antigen export to the cytosol and the function of the store-operated-Ca2+-entry regulator STIM1 are impaired. These defects result in compromised antigen cross-presentation and anti-tumor responses in 3d-mutated mice. Here, we show that UNC93B1 interacts with the calcium sensor STIM1 in the endoplasmic reticulum, a critical step for STIM1 oligomerization and activation. Expression of a constitutively active STIM1 mutant, which no longer binds UNC93B1, restores antigen degradation and cross-presentation in 3d-mutated DCs. Furthermore, ablation of STIM1 in mouse and human cells leads to a decrease in cross-presentation. Our data indicate that the UNC93B1 and STIM1 cooperation is important for calcium flux and antigen cross-presentation in DCs.

Dendritic cells (DCs) are antigen-presenting cells specialized for activating T cells to elicit effector T-cell functions. Cross-presenting DCs are a DC subset capable of presenting antigens to CD8(+) T cells and play critical roles in cytotoxic T-cell-mediated immune responses to microorganisms and cancer. Although their importance is known, the spatiotemporal dynamics of cross-presenting DCs in vivo are incompletely understood. Here, we study the T-cell zone in skin-draining lymph nodes (SDLNs) and find it is compartmentalized into regions for CD8(+) T-cell activation by cross-presenting DCs that express the chemokine (C motif) receptor 1 gene, Xcr1 and for CD4(+) T-cell activation by CD11b(+) DCs. Xcr1-expressing DCs in the SDLNs are composed of two different populations: migratory (CD103(hi)) DCs, which immigrate from the skin, and resident (CD8α(hi)) DCs, which develop in the nodes. To characterize the dynamic interactions of these distinct DC populations with CD8(+) T cells during their activation in vivo, we developed a photoconvertible reporter mouse strain, which permits us to distinctively visualize the migratory and resident subsets of Xcr1-expressing DCs. After leaving the skin, migratory DCs infiltrated to the deep T-cell zone of the SDLNs over 3 d, which corresponded to their half-life in the SDLNs. Intravital two-photon imaging showed that after soluble antigen immunization, the newly arriving migratory DCs more efficiently form sustained conjugates with antigen-specific CD8(+) T cells than other Xcr1-expressing DCs in the SDLNs. These results offer in vivo evidence for differential contributions of migratory and resident cross-presenting DCs to CD8(+) T-cell activation.

The Inside Story of Dendritic Cell Immunotherapy

Although antigen cross-presentation in dendritic cells (DCs) is critical to the initiation of most cytotoxic immune responses, the intracellular mechanisms and traffic pathways involved are still unclear. One of the most critical steps in this process, the export of internalized antigen to the cytosol, has been suggested to be mediated by Sec61. Sec61 is the channel that translocates signal peptide-bearing nascent polypeptides into the endoplasmic reticulum (ER), and it was also proposed to mediate protein retrotranslocation during ER-associated degradation (a process called ERAD). Here, we used a newly identified Sec61 blocker, mycolactone, to analyze Sec61's contribution to antigen cross-presentation, ERAD, and transport of internalized antigens into the cytosol. As shown previously in other cell types, mycolactone prevented protein import into the ER of DCs. Mycolactone-mediated Sec61 blockade also potently suppressed both antigen cross-presentation and direct presentation of synthetic peptides to CD8+ T cells. In contrast, it did not affect protein export from the ER lumen or from endosomes into the cytosol, suggesting that the inhibition of cross-presentation was not related to either of these trafficking pathways. Proteomic profiling of mycolactone-exposed DCs showed that expression of mediators of antigen presentation, including MHC class I and β2 microglobulin, were highly susceptible to mycolactone treatment, indicating that Sec61 blockade affects antigen cross-presentation indirectly. Together, our data suggest that the defective translocation and subsequent degradation of Sec61 substrates is the cause of altered antigen cross-presentation in Sec61-blocked DCs.

Enhanced Induction of HIV-specific Cytotoxic T Lymphocytes by Dendritic Cell-targeted Delivery of SOCS-1 siRNA

MHC class I presentation of peptides derived from exogenous antigens (not synthesized within the antigen-presenting cell) is called cross-presentation and is mediated by selective subsets of dendritic cells (DC). A proportion of both donor and host DC may cross-present. Although there has been many studies that have investigated the role of donor versus host DC (i.e., direct vs. indirect pathway), what role cross-presenting DC play in allograft rejection has not been determined. We recently identified an agent, cytochrome c (cytc), that selectively depletes cross-presenting DC in vivo. By administering cytc we were able to study the impact of cross-presenting DC on rejection of islets grafted into fully mismatched mice. We found that cytc protected about half of the islet allografts from rejection. Our results indicate that cross-presenting DC can make potent contributions to the immune response to islet allografts, and contend that agents such as cytc that selectively target DC heralds a novel method of immunosuppression.

Immunological Consequences of Apoptotic Cell Phagocytosis

Dendritic cells (DCs) are the most potent antigen presenting cells (APCs). Because of the difficulty in obtaining these cells directly from tissues, different sources of DCs are frequently used for in vitro experimentation and many of their biological and functional characteristics were studied using these systems. Until recently, it was assumed that specific culture conditions polarized the differentiation of either DCs or macrophages (Macs); however, it was shown that some DC culture systems in other species generate heterogeneous cell populations that can be identified according to their CD11c and MHC class II (MHC-II) expression. Following this approach, porcine DCs were directly isolated from peripheral blood or differentiated in vitro by culturing bone marrow (BM) progenitor cells or blood monocytes treated with growth factors. Mostly homogeneous monocyte-derived DCs (MoDCs) were obtained with similar phenotype and phagocytic characteristics to that of blood DCs. On the contrary, BM-derived DC (BMDC) cultures generated two distinct heterogeneous populations identified as MHC-II+ and MHC-II++ cells. BMDCs MHC-II+ had similar phenotypic and phagocytic characteristics to those of MoDCs and blood DCs. However, BMDCs MHC-II++ population expressed a higher amount of surface markers and transcribed genes associated with Macs-lineage exhibiting a higher phagocytic capacity than all the other cells. Noteworthy, every cell system expressed different genetic signatures. These results will help interpreting and re-interpreting data obtained using in vitro systems.