Unleashing the therapeutic potential of apoptotic bodies

Phan, Thanh Kha; Ozkocak, Dilara Ceyda; Poon, Ivan K. H.

doi:10.1042/bst20200225

Cited by 50 publications

(43 citation statements)

References 57 publications

(100 reference statements)

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“…extracellular vesicles) offer an attractive cell-free therapeutic alternative, they may not be a direct measure of potency when viable MSCs are infused as a cellular product. On the other hand, apoptotic MSC-derived extracellular vesicles have recently been shown to demonstrate therapeutic potential 47 , 69 – 71 . Our data provide further understanding of the mechanisms of MSC therapy and reveal opportunities for novel therapeutic interventions.…”

Section: Discussionmentioning

confidence: 99%

Mesenchymal stromal cell apoptosis is required for their therapeutic function

et al. 2021

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Multipotent mesenchymal stromal cells (MSCs) ameliorate a wide range of diseases in preclinical models, but the lack of clarity around their mechanisms of action has impeded their clinical utility. The therapeutic effects of MSCs are often attributed to bioactive molecules secreted by viable MSCs. However, we found that MSCs underwent apoptosis in the lung after intravenous administration, even in the absence of host cytotoxic or alloreactive cells. Deletion of the apoptotic effectors BAK and BAX prevented MSC death and attenuated their immunosuppressive effects in disease models used to define MSC potency. Mechanistically, apoptosis of MSCs and their efferocytosis induced changes in metabolic and inflammatory pathways in alveolar macrophages to effect immunosuppression and reduce disease severity. Our data reveal a mode of action whereby the host response to dying MSCs is key to their therapeutic effects; findings that have broad implications for the effective translation of cell-based therapies.

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Section: Discussionmentioning

confidence: 99%

Mesenchymal stromal cell apoptosis is required for their therapeutic function

et al. 2021

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“…In these particular settings, by pharmacologically targeting PANX1 using inhibitors such as trovafloxacin during the production of these tumor nuclear antigens encapsulated ApoBDs, the quantity (through enhancing ApoBD production) and quality (through elevated nuclear antigen sorting) may be improved. Using similar approach, as ApoBDs hold potential as a drug delivery system [3], therapeutic nuclear proteins, such as nuclear resident transcription factors [42], could be efficiently loaded onto ApoBDs by engineering them into host cells followed by apoptosis induction and PANX1 inhibitor treatments.…”

Section: Resultsmentioning

confidence: 99%

“…Apoptosis (a form of programmed cell death) occurs as a vital part of homeostasis and physiopathology such as chronic inflammation and infection [1,2]. Cells undergoing apoptosis often release apoptotic bodies (ApoBDs), a distinct type of membrane-bound extracellular vesicles (EVs) generally considered as 1-5 μm in size, to communicate Abbreviations: ApoBDs, apoptotic bodies; EV, extracellular vesicle; GO, gene ontology; HMGA1, high mobility group protein A1; NUP50, 50 kD nucleoporin; PANX1, pannexin 1; THYN1, thymocyte nuclear protein 1 with other cells to regulate cell clearance, tissue repair and/or immune response [3]. In contrast to previously thought, ApoBD formation is a highly co-ordinated process known as apoptotic cell disassembly consisting of three morphological steps: (i) membrane blebbing, (ii) thin membrane protrusions (e.g., apoptopodia), and (iii) fragmentation to form discrete ApoBDs.…”

Section: Introductionmentioning

confidence: 99%

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Pannexin‐1 channel regulates nuclear content packaging into apoptotic bodies and their size

et al. 2021

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Apoptotic bodies (ApoBDs), which are large extracellular vesicles exclusively released by apoptotic cells, possess therapeutically exploitable properties including biomolecule loadability and transferability. However, current limited understanding of ApoBD biology has hindered its exploration for clinical use. Particularly, as ApoBDaccompanying cargoes (e.g., nucleic acids and proteins) have major influence on their functionality, further insights into the mechanism of biomolecule sorting into ApoBDs are critical to unleash their therapeutic potential. Previous studies suggested pannexin 1 (PANX1) channel, a negative regulator of ApoBD biogenesis, can modify synaptic vesicle contents. We also reported that trovafloxacin (a PANX1 inhibitor) increases proportion of ApoBDs containing DNA. Therefore, we sought to define the role of PANX1 in regulating the sorting of nuclear content into ApoBDs. Here, using flow cytometry and label-free quantitative proteomic analyses, we showed that targeting PANX1 activity during apoptosis, via either pharmacological inhibition or genetic disruption, resulted in enrichment of both DNA and nuclear proteins in ApoBDs that were unexpectedly smaller in size. Our data suggest that PANX1, besides being a key regulator of ApoBD formation, also functions as a negative regulator of nuclear content packaging and modulator of ApoBD size. Together, our findings provide further insights into ApoBD biology and form a novel conceptual framework for ApoBD-based therapies through pharmacologically manipulating ApoBD contents.

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“…These blebs then extend radially forming long protrusions with engulfed cellular components. The bleb elongation process is regulated by other caspase-activated proteins, caspase-activated membrane channel pannexin 1 (PANX1) that negatively regulates bleb formation or in some cell types caspase-cleaved membrane receptor plexin B2 (PLXB2) that favors bleb elongation [ 103 , 104 ]. The disassembly of PANX1 promotes the release of apoptotic bodies from the dying cell through the fragmentation of the cellular structure [ 105 ].…”

Section: Extracellular Vesiclesmentioning

confidence: 99%

Microglial Extracellular Vesicles as Vehicles for Neurodegeneration Spreading

et al. 2021

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Microglial cells are the neuroimmune competent cells of the central nervous system. In the adult, microglia are responsible for screening the neuronal parenchyma searching for alterations in homeostasis. Chronic neuroinflammation plays a role in neurodegenerative disease. Indeed, microglia-mediated neuroinflammation is involved in the onset and progression of several disorders in the brain and retina. Microglial cell reactivity occurs in an orchestrated manner and propagates across the neural parenchyma spreading the neuroinflammatory signal from cell to cell. Extracellular vesicles are important vehicles of intercellular communication and act as message carriers across boundaries. Extracellular vesicles can be subdivided in several categories according to their cellular origin (apoptotic bodies, microvesicles and exosomes), each presenting, different but sometimes overlapping functions in cell communication. Mounting evidence suggests a role for extracellular vesicles in regulating microglial cell action. Herein, we explore the role of microglial extracellular vesicles as vehicles for cell communication and the mechanisms that trigger their release. In this review we covered the role of microglial extracellular vesicles, focusing on apoptotic bodies, microvesicles and exosomes, in the context of neurodegeneration and the impact of these vesicles derived from other cells in microglial cell reactivity.

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Unleashing the therapeutic potential of apoptotic bodies

Cited by 50 publications

References 57 publications

Mesenchymal stromal cell apoptosis is required for their therapeutic function

Mesenchymal stromal cell apoptosis is required for their therapeutic function

Pannexin‐1 channel regulates nuclear content packaging into apoptotic bodies and their size

Microglial Extracellular Vesicles as Vehicles for Neurodegeneration Spreading

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