Immunogenic cell death and DAMPs in cancer therapy

Krysko, Dmitri V.; Garg, Abhishek D.; Kaczmarek, Agnieszka; Krysko, Olga; Agostinis, Patrizia; Vandenabeele, Peter

doi:10.1038/nrc3380

Cited by 2,065 publications

(1,859 citation statements)

References 199 publications

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“…We found that all AC-NP formulations, with the exception of mPEG AC-NPs, successfully captured neoantigens 24 (Figure 2c, Supplementary Table 1). Notably, AC-NPs also captured a number of damage associated molecular pattern proteins (DAMPs), a broad class of pro-inflammatory molecules that have been shown to potentiate immune response 27 . Notably, we found that our AC-NPs were capable of capturing histone proteins and alarmins (including HMGB1), both of which have been shown to enhance anti-tumor immune responses (Supplementary Table 1) 27 .…”

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confidence: 99%

“…Notably, AC-NPs also captured a number of damage associated molecular pattern proteins (DAMPs), a broad class of pro-inflammatory molecules that have been shown to potentiate immune response 27 . Notably, we found that our AC-NPs were capable of capturing histone proteins and alarmins (including HMGB1), both of which have been shown to enhance anti-tumor immune responses (Supplementary Table 1) 27 . Our data confirm that AC-NPs capture a myriad of TDPAs that are released after radiotherapy.…”

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Antigen-capturing nanoparticles improve the abscopal effect and cancer immunotherapy

et al. 2017

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Immunotherapy holds tremendous promise for improving cancer treatment1. Administering radiotherapy with immunotherapy has been shown to improve immune responses and can elicit an “abscopal effect”2. Unfortunately, response rates for this strategy remain low3. Herein, we report an improved cancer immunotherapy approach that utilizes antigen-capturing nanoparticles (AC-NPs). We engineered several AC-NPs formulations and demonstrated that the set of protein antigens captured by each AC-NP formulation is dependent upon NP surface properties. We showed that AC-NPs deliver tumor specific proteins to antigen-presenting cells and significantly improve the efficacy of αPD-1 treatment using the B16F10 melanoma model, generating up to 20% cure rate as compared to 0% without AC-NPs. Mechanistic studies revealed that AC-NPs induced an expansion of CD8+ cytotoxic T cells and increased both CD4+/Treg and CD8+/Treg ratios. Our work presents a novel strategy for improving cancer immunotherapy with nanotechnology.

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Antigen-capturing nanoparticles improve the abscopal effect and cancer immunotherapy

et al. 2017

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“…Accumulating evidence now indicates that (at least some) anticancer agents actively stimulate tumor-specific immune responses, which in many cases account for long-term therapeutic successes. [1][2][3][4] Chemotherapy (as well as some forms of radiotherapy) can exert immunostimulatory effects via two alternative, although non-exclusive, mechanisms. First, some cytotoxic anticancer agents, including anthracyclines and oxaliplatin (OXA), are capable of triggering an immunogenic variant of apoptosis known as immunogenic cell death (ICD), 5,6 de facto converting dying cancer cells into a therapeutic vaccine.…”

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“…2,11,12 Thus, the subcutaneous injection of cancer cells that are succumbing to ICD, but not of cells undergoing conventional apoptosis or necrosis, elicits a T-cell-mediated immune response protecting histocompatible mice against a subsequent challenge with tumor cells of the same type. 2,3,13 Of note, most inducers of apoptosis and necrosis fail to trigger ICD. However, a few chemotherapeutics, including anthracyclines, 7,8 OXA, 14 cyclophosphamide, 15 and -to some extent -microtubular inhibitors, 16 as well as cardiac glycosides, [17][18][19] potently do so.…”

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“…ER stress culminates in the translocation of the ER chaperone calreticulin (CRT) to the cell surface, thereby generating an 'eat-me' signal for DCs. 3,22 Autophagy facilitates the release of ATP from dying cells, 23 constituting both a 'find-me' signal for the recruitment of DCs and their precursors 24 and a proinflammatory stimulus that -upon binding to the purinergic receptor P2RX7 -elicits the activation of the NOD-like receptor family, pyrin domain containing 3 (NLRP3) inflammasome within DCs and macrophages. 25,26 In addition, ICD is associated with the postmortem release of the non-histone chromatin-binding protein high-mobility group box 1 (HMGB1) into the extracellular space, allowing HMGB1 to bind Toll-like receptor 4 on DCs and thus stimulate their antigenpresenting functions.…”

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Molecular mechanisms of ATP secretion during immunogenic cell death

et al. 2013

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The immunogenic demise of cancer cells can be induced by various chemotherapeutics, such as anthracyclines and oxaliplatin, and provokes an immune response against tumor-associated antigens. Thus, immunogenic cell death (ICD)-inducing antineoplastic agents stimulate a tumor-specific immune response that determines the long-term success of therapy. The release of ATP from dying cells constitutes one of the three major hallmarks of ICD and occurs independently of the two others, namely, the pre-apoptotic exposure of calreticulin on the cell surface and the postmortem release of high-mobility group box 1 (HMBG1) into the extracellular space. Pre-mortem autophagy is known to be required for the ICD-associated secretion of ATP, implying that autophagy-deficient cancer cells fail to elicit therapy-relevant immune responses in vivo. However, the precise molecular mechanisms whereby ATP is actively secreted in the course of ICD remain elusive. Using a combination of pharmacological screens, silencing experiments and techniques to monitor the subcellular localization of ATP, we show here that, in response to ICD inducers, ATP redistributes from lysosomes to autolysosomes and is secreted by a mechanism that requires the lysosomal protein LAMP1, which translocates to the plasma membrane in a strictly caspase-dependent manner. The secretion of ATP additionally involves the caspase-dependent activation of Rho-associated, coiled-coil containing protein kinase 1 (ROCK1)-mediated, myosin II-dependent cellular blebbing, as well as the opening of pannexin 1 (PANX1) channels, which is also triggered by caspases. Of note, although autophagy and LAMP1 fail to influence PANX1 channel opening, PANX1 is required for the ICD-associated translocation of LAMP1 to the plasma membrane. Altogether, these findings suggest that caspase-and PANX1-dependent lysosomal exocytosis has an essential role in ATP release as triggered by immunogenic chemotherapy.

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Autophagy, the innate immune response and cancer

Gerada

Ryan

2020

Molecular Oncology

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Both autophagy, a cellular recycling process, and the innate immune response can have different effects on tumour formation at different stages. Interestingly, autophagy and the innate immune response interact during tumorigenesis to have both tumour‐promoting and tumour‐inhibiting affects. By dissecting the interaction between autophagy and the innate immune response during tumour formation, novel therapeutic strategies may be identified.

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Immunogenic cell death and DAMPs in cancer therapy

Cited by 2,065 publications

References 199 publications

Antigen-capturing nanoparticles improve the abscopal effect and cancer immunotherapy

Antigen-capturing nanoparticles improve the abscopal effect and cancer immunotherapy

Molecular mechanisms of ATP secretion during immunogenic cell death

Autophagy, the innate immune response and cancer

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