Immunogenic cell death significantly contributes to the success of anti-cancer therapies, but immunogenicity of different cell death modalities widely varies. Ferroptosis, a form of cell death that is characterized by iron accumulation and lipid peroxidation, has not yet been fully evaluated from this perspective. Here we present an inducible model of ferroptosis, distinguishing three phases in the process—‘initial’ associated with lipid peroxidation, ‘intermediate’ correlated with ATP release and ‘terminal’ recognized by HMGB1 release and loss of plasma membrane integrity—that serves as tool to study immune cell responses to ferroptotic cancer cells. Co-culturing ferroptotic cancer cells with dendritic cells (DC), reveals that ‘initial’ ferroptotic cells decrease maturation of DC, are poorly engulfed, and dampen antigen cross-presentation. DC loaded with ferroptotic, in contrast to necroptotic, cancer cells fail to protect against tumor growth. Adding ferroptotic cancer cells to immunogenic apoptotic cells dramatically reduces their prophylactic vaccination potential. Our study thus shows that ferroptosis negatively impacts antigen presenting cells and hence the adaptive immune response, which might hinder therapeutic applications of ferroptosis induction.
Chronic non-healing wounds are a major complication of diabetes, which impacts 1 in 10 people worldwide. Dying cells in the wound perpetuate the inflammation and contribute to dysregulated tissue repair 1-3 . Here, we reveal the membrane transporter Slc7a11 as a molecular 'brake' on efferocytosis, the process by which dying cells are removed, and that inhibiting Slc7a11 can accelerate wound healing. First, transcriptomics of efferocytic dendritic cells identified upregulation of several Slc7 gene family members. In further analyses, pharmacological inhibition, siRNA knockdown, or deletion of Slc7a11 enhanced dendritic cell efferocytosis. Interestingly, Slc7a11 was highly expressed in skin dendritic cells, and scRNAseq of inflamed skin showed Slc7a11 upregulation in innate immune cells. In a mouse model of excisional skin wounding, loss of Slc7a11 expression or inhibition accelerated healing dynamics and reduced apoptotic cell load in the wound. Mechanistic studies revealed a link between Slc7a11, glucose homeostasis, and diabetes. Slc7a11-deficient dendritic cells relied on glycogen store-derived aerobic glycolysis for improved efferocytosis, and transcriptomics of efferocytic Slc7a11-deficient dendritic cells identified genes linked to gluconeogenesis and diabetes. Further, Slc7a11 expression was higher in the wounds of diabetic-prone db/db mice, and targeting Slc7a11 accelerated their wound healing. The faster healing was also linked to the release of TGF- family member GDF15 from efferocytic dendritic cells. Collectively, Slc7a11 is a negative regulator of efferocytosis, and removing this brake improves wound healing, with significant implications for diabetic wound management.
IL-1β-driven amyloid plaque clearance is associated with an expansion of transcriptionally reprogrammed microglia
BackgroundNeuroinflammation is thought to contribute to the pathogenesis of Alzheimer’s disease (AD), yet numerous studies have demonstrated a beneficial role for neuroinflammation in amyloid plaque clearance. We have previously shown that sustained expression of IL-1β in the hippocampus of APP/PS1 mice decreases amyloid plaque burden independent of recruited CCR2+ myeloid cells, suggesting resident microglia as the main phagocytic effectors of IL-1β-induced plaque clearance. To date, however, the mechanisms of IL-1β-induced plaque clearance remain poorly understood.MethodsTo determine whether microglia are involved in IL-1β-induced plaque clearance, APP/PS1 mice induced to express mature human IL-1β in the hippocampus via adenoviral transduction were treated with the Aβ fluorescent probe methoxy-X04 (MX04) and microglial internalization of fibrillar Aβ (fAβ) was analyzed by flow cytometry and immunohistochemistry. To assess microglial proliferation, APP/PS1 mice transduced with IL-1β or control were injected intraperitoneally with BrdU and hippocampal tissue was analyzed by flow cytometry. RNAseq analysis was conducted on microglia FACS sorted from the hippocampus of control or IL-1β-treated APP/PS1 mice. These microglia were also sorted based on MX04 labeling (MX04+ and MX04− microglia).ResultsResident microglia (CD45loCD11b+) constituted > 70% of the MX04+ cells in both Phe- and IL-1β-treated conditions, and < 15% of MX04+ cells were recruited myeloid cells (CD45hiCD11b+). However, IL-1β treatment did not augment the percentage of MX04+ microglia nor the quantity of fAβ internalized by individual microglia. Instead, IL-1β increased the total number of MX04+ microglia in the hippocampus due to IL-1β-induced proliferation. In addition, transcriptomic analyses revealed that IL-1β treatment was associated with large-scale changes in the expression of genes related to immune responses, proliferation, and cytokine signaling.ConclusionsThese studies show that IL-1β overexpression early in amyloid pathogenesis induces a change in the microglial gene expression profile and an expansion of microglial cells that facilitates Aβ plaque clearance.
Macrophage antibody dependent cellular phagocytosis (ADCP) is a major cytotoxic mechanism for both therapeutic unconjugated monoclonal antibodies (mAb) such as rituximab, and antibody induced hemolytic anemia and immune thrombocytopenia. Here, we studied the mechanisms controlling the rate and capacity of macrophages to carry out ADCP in settings of high target to effector cell ratio such as that seen in patients with circulating tumor burden in leukemic phase disease. Using quantitative live-cell imaging of primary human and mouse macrophages we found that, upon initial challenge with mAb-opsonized lymphocytes, macrophages undergo a brief burst (<1hr) of rapid phagocytosis which is then invariably followed by a sharp reduction in phagocytic activity that can persist for days. This previously unknown refractory period of ADCP, or "hypophagia," was observed in all macrophage/mAb/target cell conditions tested in vitro, and was also seen in vivo in Kupffer cells from mice induced to undergo successive rounds of ⍺CD20 mAb-dependent clearance of circulating B cells. Importantly, hypophagia had no effect on antibody-independent phagocytosis and did not alter macrophage viability. In mechanistic studies we found that the rapid loss of activating Fc receptors from the surface and their subsequent proteolytic degradation is the primary mechanism responsible for the loss of ADCP activity in hypophagia. These data suggest hypophagia is a critical limiting step in macrophage-mediated clearance of cells via ADCP and that understanding such limitations to innate immune system cytotoxic capacity will aid in the development of mAb regimens that could optimize ADCP and improve patient outcome.
Phagocytosis is a dynamic process central to immunity and tissue homeostasis. Current phagocytosis quantitation methods largely rely on indirect or static measurements, such as target clearance or dye uptake, and thus provide limited information about engulfment rates or target processing. Improved kinetic measurements of phagocytosis could provide useful, basic insights in many areas. We present a live-cell, time-lapse, high-content microscopy imaging method based on the detection and quantitation of fluorescent dye “voids” within phagocytes that result from target internalization to quantitate phagocytic events with high temporal resolution. Using this method, we measure target cell densities and antibody concentrations needed for optimal antibody-dependent cellular phagocytosis. We compare void formation and dye uptake methods for phagocytosis detection and examine the connection between target cell engulfment and phagolysosomal processing. We demonstrate how this approach can be used to measure distinct forms of phagocytosis, and changes in macrophage morphology during phagocytosis related to both engulfment and target degradation. Our results provide a high-resolution method for quantitating phagocytosis that provides opportunities to better understand the cellular and molecular regulation of this fundamental biological process.
Unconjugated monoclonal antibodies (mAb) have revolutionized the treatment of B-cell malignancies. These targeted drugs can activate innate immune cytotoxicity for therapeutic benefit. mAb activation of the complement cascade results in complement-dependent cytotoxicity (CDC) and complement receptor-mediated antibody-dependent cellular phagocytosis (cADCP). Clinical and laboratory studies have showed that CDC is therapeutically important. In contrast, the biological role and clinical effects of cADCP are less well understood. This review summarizes the available data on the role of complement activation in the treatment of mature B-cell malignancies and proposes future research directions that could be useful in optimizing the efficacy of this important class of drugs.
Background Combinations of different targeted therapies, including Bruton tyrosine kinase (BTK) inhibitors and anti-CD20 monoclonal antibodies (mAbs) could improve treatment for CLL. Unexpectedly, the combination of ibrutinib (IBR) with rituximab did not show additional clinical benefit. However, IBR inhibits many off-target molecules that may limit therapeutic mAb clinical effectiveness and a more selective BTK inhibitor, such as acalabrutinib (ACALA), could be more effective in combination with mAb therapy. Initial data from the ELEVATE TN trial support this possibility. IBR off-target effects on antibody-dependent cellular phagocytosis (ADCP), the major mechanism of therapeutic mAb activity could explain this difference. Additionally, IBR induces a higher and longer duration increase in circulating lymphocytes than ACALA. IBR off-target effects on efferocytosis, another phagocytic process involved in apoptotic cell removal, might explain this difference. Methods Using state-of-the-art direct kinetic measurements of phagocytosis by time-lapse video, (Chu et al. J Cell Sci 2020;133:jcs237883) we investigated the effects of IBR and ACALA on phagocytosis (ADCP or efferocytosis) by human monocyte-derived macrophages (hMDM) in vitro. Live cell time-lapse video of 10 μg/ml rituximab (Genentech) mediated ADCP of CLL cells by CellTracker Deep Red (CTDR, Thermofisher) labeled hMDM (20:1 CLL:hMDM cell ratio) either untreated or treated with IBR or ACALA (3-fold serial dilutions from 100 to 0.41 μM) was imaged in a stage-top environmental chamber (37°C and 5% CO2) mounted onto a Nikon Ti-Eclipse inverted microscope with an ELWD 20x/0.45NA S Plan Fluor Ph1 objective and an Andor Zyla 5.5 sCMOS camera. Images were captured sequentially every 4 min over 2.8 h. For each experiment (n = 18), duplicate or triplicate wells for each drug concentration were imaged. For efferocytosis, live cell time-lapse video imaging of phagocytosis of pHrodo iFL Red STP ester (pHrodo Red, Thermo Fisher Scientific) labeled apoptotic CLL cells by CTDR-labeled hMDM (20:1 CLL:hMDM cell ratio) either untreated or treated with IBR or ACALA (2-fold serial dilutions from 10 to 1.25 μM) was collected every 4 min over 2.8 h. For each experiment (n = 7), duplicate or triplicate wells for each drug concentration was imaged and analyzed. Finally, for efferocytosis, the intensity of pHrodo Red dye, a pH-sensitive dye that increases in intensity with acidic pH, as found in the endolysosomes, was measured in the pHrodo Red color channel and analyzed. Results IBR significantly inhibited ADCP at all measured drug concentrations (0.41 μM, p < 0.05; 1.2 μM, p < 0.01; 3.7 - 100 μM, p < 0.001). The mean peak free drug concentration (Cmax) achieved clinically by standard doses for IBR is ~0.5 μM. ACALA only significantly inhibited ADCP at the highest concentration (100 μM, p < 0.001). The Cmax achieved clinically by standard doses for ACALA is ~1.2 μM. ACALA did not inhibit efferocytosis or subsequent transition to endolysosomal compartment at all tested concentrations (p > 0.05). IBR did not inhibit efferocytosis (p > 0.05) and only inhibited transition to endolysosomal compartment at highest concentration tested (10 μM, p < 0.01) Conclusion Our study shows that BTK inhibition does not block ADCP and a more selective BTK inhibitor may prove effective in combination with therapeutic anti-CD20 mAbs. IBR off-target inhibition specifically blocks ADCP and not efferocytosis. Thus, IBR off-target inhibition of ADCP should be via proximal signaling by antibody Fc receptors and not subsequent downstream phagocytic mechanisms in common with efferocytosis. These results also imply the lack of BTK and IBR off-target molecules involvement in efferocytosis. Finally, the increased lymphocytosis seen with IBR compared to ACALA treatment in CLL cannot be explained by IBR off-target effects on efferocytosis. These findings provide a critical understanding of macrophage phagocytosis reduction by BTK inhibitor selectivity that will have important consequences for the development of combination targeted therapies with mAbs. Disclosures Chu: Acerta Pharma/AstraZeneca: Research Funding; Pfizer: Current equity holder in publicly-traded company, Divested equity in a private or publicly-traded company in the past 24 months; TG Therapeutics: Research Funding. Izumi:AstraZeneca: Current equity holder in publicly-traded company; Acerta Pharma: Current equity holder in private company, Ended employment in the past 24 months, Patents & Royalties: Acalabrutinib patents (no royalties). Munugalavadla:Gilead Sciences: Current equity holder in publicly-traded company; AstraZeneca: Current equity holder in publicly-traded company; Acerta Pharma: Current Employment. Barr:Gilead: Consultancy; Morphosys: Consultancy; TG therapeutics: Consultancy, Research Funding; Seattle Genetics: Consultancy; Celgene: Consultancy; AstraZeneca: Consultancy, Research Funding; Janssen: Consultancy; Merck: Consultancy; Genentech: Consultancy; Abbvie/Pharmacyclics: Consultancy, Research Funding; Verastem: Consultancy. VanDerMeid:Acerta Pharma / AstraZeneca: Research Funding. Elliott:Acerta Pharma / AstraZeneca: Research Funding. Zent:Mentrik Biotech: Research Funding; TG Therapeutics, Inc: Research Funding; Acerta / Astra Zeneca: Research Funding.
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