Why Cells and Viruses Cannot Survive without an ESCRT
Abstract
:1. Introduction
2. The ESCRT Machinery: An Overview
3. ESCRT Machinery Functions in Fundamental Cellular Pathways
3.1. ESCRTs Involvement in MVB Biogenesis
3.2. Role of ESCRT Machinery in Autophagy
3.3. Role of the ESCRT Machinery in Cytokinesis
3.4. Involvement of the ESCRT Machinery in Damage Repair of Cellular Membranes
3.4.1. Plasma Membrane Repair
3.4.2. Nuclear Envelope Maintenance and Repair
3.4.3. Endolysosomal Membrane Repair
4. ESCRT Machinery and Viral Replication Cycle
4.1. ESCRT Machinery and Viral Entry
4.2. ESCRT Machinery Involvement in the Formation of Viral Replication/Assembly Compartments
4.3. ESCRT Machinery and Viral Egress from Infected Cells
4.4. EVs and Autophagy in Viral Transmission
5. The Travel of Herpes Simplex Virus Type 1 from the Nucleus to the Extracellular Environment: Is There a Role for the ESCRT Machinery?
6. Conclusions and Outlook
Author Contributions
Funding
Conflicts of Interest
References
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Cellular Process | Key Player/s | Effect of Silencing | References |
---|---|---|---|
MVB Biogenesis | ESCRT-0 (HRS) ESCRT-I (TSG101) ESCRT-III/VPS4 | HRS depletion: enlarged MVBs with few ILVs TSG101 depletion: MVB formation strongly reduced ESCRT-III/Vps24 depletion: smaller MVBs in clusters HRS TSG101, Vps22 and Vps24 co-depletion: MVBs and ILVs still formed | [53,128,129,130] |
Autophagy | ESCRT-I (VPS37A) ESCRT-III (CHMP2A)/VPS4 | VPS37A depletion: accumulation of phagophores due to defects in autophagosome completion CHMP2A depletion: accumulation of immature autophagosomal structures; impairment of autophagic flux; inhibition of phagophore sealing during mitophagy CHMP2A, CHMP3, CHMP7 depletion: increase in immature autophagosomal membranes under starvation CHMP2A, CHMP4B and VPS4 depletion: inhibition of mitophagy | [66,67] |
Cytokinesis | ESCRT-I (TSG101)/ESCRT-II Alix ESCRT-III (CHMP-6,CHMP4B,CHMP4C)/VPS4 | Alix depletion: an increase in multinuclear cells; furrow regression; a failure in CHMP4C recruitment to the midbody; CHMP4B still recruited TSG101 and Alix co-depletion: failure in CHMP4B recruitment to the midbody; multinucleation non aggravated Alix, VPS22, and CHMP6 co-depletion: CHMP4B is not recruited to the intercellular bridge CHMP4C depletion: altered cytokinetic arrest in the presence of chromosomal problems; furrow regression and binucleation | [73,74,80,88,131] |
Cell Membrane Repair | ESCRT-I (TSG101) Alix ESCRT-III (CHMP4B)/VPS4 | Alix, CHMP2B VPS4 depletion: failure of the repairing process followed by cell death (CHMP4B and VPS4 silencing) CHMP2A depletion: impairment of the repairing process CHMP3 depletion: no significant effect | [99,101] |
Nuclear Membrane Repair | ESCRT-III (CHMP4B, CHMP7)/VPS4 | Alix, HD-PTP, HRS, TSG101 depletion: no effects on CHMP4B recruitment to the site of ruptures CHMP7depletion: failure of CHMP4B recruitment to the nuclear envelope | [107,108] |
Lysosomal Membrane Repair | ESCRT-I (TSG101) Alix ESCRT-III (CHMP2A, CHMP4B)/VPS4 | HRS depletion: no effect on CHMP4B recruitment to lysosomes TSG101 depletion: consistent delay in CHMP4B recruitment CHMP2A depletion: increased accumulation of CHMP4B on damaged lysosomes Alix depletion: no detectable effect on CHM4B recruitment TSG101 and Alix co-depletion: almost complete abrogation of CHMP4B recruitment; failure of recovering of damaged lysosomes | [118,119] |
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Calistri, A.; Reale, A.; Palù, G.; Parolin, C. Why Cells and Viruses Cannot Survive without an ESCRT. Cells 2021, 10, 483. https://doi.org/10.3390/cells10030483
Calistri A, Reale A, Palù G, Parolin C. Why Cells and Viruses Cannot Survive without an ESCRT. Cells. 2021; 10(3):483. https://doi.org/10.3390/cells10030483
Chicago/Turabian StyleCalistri, Arianna, Alberto Reale, Giorgio Palù, and Cristina Parolin. 2021. "Why Cells and Viruses Cannot Survive without an ESCRT" Cells 10, no. 3: 483. https://doi.org/10.3390/cells10030483
APA StyleCalistri, A., Reale, A., Palù, G., & Parolin, C. (2021). Why Cells and Viruses Cannot Survive without an ESCRT. Cells, 10(3), 483. https://doi.org/10.3390/cells10030483