The marine natural product mimic MPM-1 is cytolytic and induces DAMP release from human cancer cell lines.

Bioprospecting contributes to the discovery of new molecules with anticancer properties. Compounds with cytolytic activity and the ability to induce immunogenic cell death can be administered as intratumoral injections with the aim to activate anti-tumor immune responses by causing the release of tumor antigens as well as damage-associated molecular patterns (DAMPs) from dying cancer cells. In the present study, we report the cytolytic and DAMP-releasing effects of a new natural product mimic termed MPM-1 that was inspired by the marine Eusynstyelamides. We found that MPM-1 rapidly killed cancer cells in vitro by inducing a necrosis-like death, which was accompanied by lysosomal swelling and perturbation of autophagy in HSC-3 (human oral squamous cell carcinoma) cells. MPM-1 also induced release of the DAMPs adenosine triphosphate (ATP) and high mobility group box 1 (HMGB1) from Ramos (B-cell lymphoma) and HSC-3 cells, as well as cell surface expression of calreticulin in HSC-3 cells. This indicates that MPM-1 has the ability to induce immunogenic cell death, further suggesting that it may have potential as a novel anticancer compound.

Damage-associated molecular patterns (DAMPs) related to immunogenic cell death are differentially triggered by clinically relevant chemotherapeutics in lung adenocarcinoma cells.

BACKGROUND: Chemotherapeutics can stimulate immune antitumor response by inducing immunogenic cell death (ICD), which is activated by Damage-Associated Molecular Patterns (DAMPs) like the exposure of calreticulin (CRT) on the cell surface, the release of ATP and the secretion of High Mobility Group Box 1 (HMGB1). METHODS: Here, we investigated the levels of ICD-associated DAMPs induced by chemotherapeutics commonly used in the clinical practice of non-small cell lung cancer (NSCLC) and the association of these DAMPs with apoptosis and autophagy. A549 human lung adenocarcinoma cells were treated with clinically relevant doses of cisplatin, carboplatin, etoposide, paclitaxel and gemcitabine. We assessed ICD-associated DAMPs, cell viability, apoptosis and autophagy in an integrated way. RESULTS: Cisplatin and its combination with etoposide induced the highest levels of apoptosis, while etoposide was the less pro-apoptotic treatment. Cisplatin also induced the highest levels of ICD-associated DAMPs, which was not incremented by co-treatments. Etoposide induced the lower levels of ICD and the highest levels of autophagy, suggesting that the cytoprotective role of autophagy is dominant in relation to its pro-ICD role. High levels of CRT were associated with better prognosis in TCGA databank. In an integrative analysis we found a strong positive correlation between DAMPs and apoptosis, and a negative correlation between cell number and ICD-associated DAMPs as well as between autophagy and apoptosis markers. We also purpose a mathematical integration of ICD-associated DAMPs in an index (IndImunnog) that may represent with greater biological relevance this process. Cisplatin-treated cells showed the highest IndImmunog, while etoposide was the less immunogenic and the more pro-autophagic treatment. CONCLUSIONS: Cisplatin alone induced the highest levels of ICD-associated DAMPs, so that its combination with immunotherapy may be a promising therapeutic strategy in NSCLC.

Tranexamic acid suppresses the release of mitochondrial DAMPs and reduces lung inflammation in a murine burn model.

BACKGROUND: Severe burn injuries are known to initiate a profound systemic inflammatory response (SIRS) that may lead to burn shock and other SIRS-related complications. Damage-associated molecular patterns (DAMPs) are important early signaling molecules that initiate SIRS after burn injury. Previous work in a rodent model has shown that application of a topical immune modulator (p38MAPK inhibitor) applied directly to the burn wound decreases cytokine expression, reduces pulmonary inflammation and edema. Our group has demonstrated that tranexamic acid (TXA)-in addition to its use as an antifibrinolytic-has cell protective in vitro effects. We hypothesized that administration of TXA after burn injury would attenuate DAMP release and reduce lung inflammation. METHODS: C57/BL6 male mice underwent a 40% Total Body Surface Area (TBSA) scald burn. Sham animals underwent the same procedure in room temperature water. One treatment group received the topical application of p38MAPK inhibitor after burn injury. The other treatment group received an intraperitoneal administration of TXA after burn injury. Animals were sacrificed at 5 hours. Plasma was collected by cardiac puncture. MtDNA levels in plasma were determined by quantitative Polymerase Chain Reaction (qPCR). Syndecan-1 levels in plasma were measured by ELISA. Lungs were harvested, fixed, and paraffin-embedded. Sections of lungs were stained for antigen to detect macrophages. RESULTS: Topical p38MAPK inhibitor and TXA significantly attenuated mtDNA release. Both TXA and the topical p38MAPK inhibitor reduced lung inflammation as represented by decreased macrophage infiltration. Syndecan-1 levels showed no difference between burn and treatment groups. CONCLUSION: Both p38 MAPK inhibitor and TXA demonstrated the ability to attenuate burn-induced DAMP release and lung inflammation. Beyond its role as an antifibrinolytic, TXA may have significant anti-inflammatory effects pertinent to burn resuscitation. Further study is required; however, TXA may be a useful adjunct in burn resuscitation.

Immunological effects of photodynamic therapy in the treatment of actinic keratosis and squamous cell carcinoma.

The use of photodynamic therapy is extensive, due to its antitumoral, antibacterial and photorejuvenation effects. It destroys tumor via direct cell destruction and indirectly via vascular shutdown, induction of acute local inflammatory response and activation of the immune system. Both innate and adaptive immune cells are involved in the immunological effects of photodynamic therapy. In addition to UV-induced DNA damage, inflammation and immunosuppression are also essential elements in the pathogenesis of actinic keratosis. Both immunosuppression induced by UV and defective immune response to dysplastic keratinocytes may be the target of photodynamic therapy to eliminate actinic keratosis. These elements are discussed in the present review, highlighting the possible mechanism of photodynamic therapy to effectively treat actinic keratosis.

Staphylococcus aureus Virulent PSMα Peptides Induce Keratinocyte Alarmin Release to Orchestrate IL-17-Dependent Skin Inflammation.

Staphylococcus aureus commonly colonizes the epidermis, but the mechanisms by which the host senses virulent, but not commensal, S. aureus to trigger inflammation remain unclear. Using a murine epicutaneous infection model, we found that S. aureus-expressed phenol-soluble modulin (PSM)α, a group of secreted virulence peptides, is required to trigger cutaneous inflammation. PSMα induces the release of keratinocyte IL-1α and IL-36α, and signaling via IL-1R and IL-36R was required for induction of the pro-inflammatory cytokine IL-17. The levels of released IL-1α and IL-36α, as well as IL-17 production by γδ T cells and ILC3 and neutrophil infiltration to the site of infection, were greatly reduced in mice with total or keratinocyte-specific deletion of the IL-1R and IL-36R signaling adaptor Myd88. Further, Il17a-/-f-/- mice showed blunted S. aureus-induced inflammation. Thus, keratinocyte Myd88 signaling in response to S. aureus PSMα drives an IL-17-mediated skin inflammatory response to epicutaneous S. aureus infection.