Phosphatidylserine Vesicles Enable Efficient En Bloc Transmission of Enteroviruses

Chen, Ying Han; Du, Wenli; Hagemeijer, Marne C.; Takvorian, Peter M.; Pau, Cyrilla; Cali, Ann; Brantner, Christine A.; Stempinski, Erin; Connelly, Patricia S.; Chieh, Hsin; Jiang, Ping; Wimmer, Eckard; Altan‐Bonnet, Grégoire; Altan‐Bonnet, Nihal

doi:10.1016/j.cell.2015.01.032

Cited by 410 publications

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“…These enteroviral vesicles are much larger than eHAV, and contain a much greater number of viral capsids than eHAV vesicles (2,6). Their size resembles extracellular vesicles and autophagous blebs shed from the plasma membrane, and is distinct from MVB-derived exosomes that are generally much smaller (<150 nm) and similar to eHAV (2,17).…”

Section: Discussionmentioning

confidence: 99%

“…Recent studies have brought increasing recognition to the fact that multiple members of the Picornaviridae are released from cells enclosed in membranous vesicles in the absence of cell lysis (2)(3)(4)(5)(6). This mode of cellular egress has been suggested to play an important role in disease pathogenesis by masking viral antigens from the immune system (2) or increasing the number of viral genomes delivered to single infected cells (6).…”

Section: Discussionmentioning

confidence: 99%

“…This mode of cellular egress has been suggested to play an important role in disease pathogenesis by masking viral antigens from the immune system (2) or increasing the number of viral genomes delivered to single infected cells (6). However, many questions remain concerning the mechanisms underlying the release of virus in extracellular vesicles.…”

Section: Discussionmentioning

confidence: 99%

“…Coxsackievirus B, poliovirus, and many other members of the genus Enterovirus typically cause lytic infections in cultured cells. However, viruses in this genus are also released within extracellular vesicles before cell lysis, often with many capsids packaged within a single vesicle (4)(5)(6). The cellular egress of these classically nonenveloped viruses in membrane-bound vesicles has blurred the distinction between enveloped and nonenveloped viruses and has important implications for pathogenesis (2).…”

mentioning

confidence: 99%

“…Although the size and density of eHAV vesicles are consistent with an exosome-like origin in multivesicular bodies (MVBs) (2, 3), eHAV biogenesis remains incompletely defined and the protein composition of the membranes surrounding the quasi-enveloped capsid is unknown. In contrast, the extracellular vesicles involved in egress of enteroviruses have been suggested to be derived from autophagosomes, as they contain lipidated LC3-II, a marker of autophagy, and disrupting autophagy blocks their release (4,6). However, the protein composition of these extracellular vesicles also has yet to be comprehensively investigated.…”

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confidence: 99%

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Protein composition of the hepatitis A virus quasi-envelope

McKnight

Xie

González‐López

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

124

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The Picornaviridae are a diverse family of RNA viruses including many pathogens of medical and veterinary importance. Classically considered "nonenveloped," recent studies show that some picornaviruses, notably hepatitis A virus (HAV; genus Hepatovirus) and some members of the Enterovirus genus, are released from cells nonlytically in membranous vesicles. To better understand the biogenesis of quasienveloped HAV (eHAV) virions, we conducted a quantitative proteomics analysis of eHAV purified from cell-culture supernatant fluids by isopycnic ultracentrifugation. Amino acid-coded mass tagging (AACT) with stable isotopes followed by tandem mass spectrometry sequencing and AACT quantitation of peptides provided unambiguous identification of proteins associated with eHAV versus unrelated extracellular vesicles with similar buoyant density. Multiple peptides were identified from HAV capsid proteins (53.7% coverage), but none from nonstructural proteins, indicating capsids are packaged as cargo into eHAV vesicles via a highly specific sorting process. Other eHAVassociated proteins (n = 105) were significantly enriched for components of the endolysosomal system (>60%, P < 0.001) and included many common exosome-associated proteins such as the tetraspanin CD9 and dipeptidyl peptidase 4 (DPP4) along with multiple endosomal sorting complex required for transport III (ESCRT-III)-associated proteins. Immunoprecipitation confirmed that DPP4 is displayed on the surface of eHAV produced in cell culture or present in sera from humans with acute hepatitis A. No LC3-related peptides were identified by mass spectrometry. RNAi depletion studies confirmed that ESCRT-III proteins, particularly CHMP2A, function in eHAV biogenesis. In addition to identifying surface markers of eHAV vesicles, the results support an exosome-like mechanism of eHAV egress involving endosomal budding of HAV capsids into multivesicular bodies.exosome | multivesicular body | ESCRT | extracellular vesicle | picornavirus T he Picornaviridae are a large and diverse family of positivestrand RNA viruses that include numerous pathogens (1). Classically considered "nonenveloped," these viruses package their single-stranded genomes within stable icosahedral protein capsids that are released from cells following cell lysis. However, recent work has revealed that several picornaviruses gain egress from cells in a nonlytic fashion within the lumen of extracellular vesicles shed from the cell. Most notably, hepatitis A virus (HAV; genus Hepatovirus), an important cause of enterically transmitted hepatitis in humans, replicates without cytopathic effect and is released from cells as membrane-wrapped, "quasienveloped" (eHAV) virions similar in size and density to exosomes (2). eHAV virions have been identified in sera collected from persons with acute hepatitis A, as well as in supernatant fluids of infected cell cultures. These virions are completely cloaked in host-derived membranes that protect the capsid from neutralizing antibody until the quasi-envelope is degraded wi...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Protein composition of the hepatitis A virus quasi-envelope

McKnight

Xie

González‐López

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

124

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Antiviral Strategies Against (Non‐polio) Picornaviruses

Abdelnabi

Baggen

Mirabelli

et al. 2021

Methods and Principles in Medicinal Chemistry

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Role of Protein–Lipid Interactions in Viral Entry

et al. 2022

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description, lipid raft has generated equal levels of enthusiasm and controversy in the research community. [1,5] This controversy arises from the lack of suitable tools to unravel the existence of such nanostructures in living organisms at resting state. [5][6][7] Despite this long-lasting controversy, what we can ascertain is that the alteration of membrane physicochemical properties such as curvature, elasticity, or fluidity can have a direct effect in membrane protein properties and function, and finally, in viral infectivity. [8,9] Therefore, viruses are a clear example of how cell membrane physicochemical properties are of high evolutionary relevance, as they are exploited by these pathogens in the infection cycle.Viruses are obligatory intracellular parasites that are simple in structure and compositions but hijack the host cellular mechanisms to ensure viral infection and progression. Naked viruses contain a genome encased in a protein shell called capsid, which in the case of enveloped viruses is surrounded by a host cell-derived lipid membrane.The viral entry process is a complex and determinant step necessary for establishing viral infection since viral replication occurs exclusively inside the host cell. It compiles sequential events starting from viral attachment to the host cell to penetration to cell cytoplasm. Attachment of virus particles to host cell molecules that act as cellular receptors, such as lipid or proteins, determines cellular tropism and, therefore, specificity. After adhesion, virus penetration occurs either at the plasma membrane or the endomembrane system upon environment acidification. For enveloped viruses, transfer is achieved by fusion of the viral and cellular membranes. The fusion event is catalyzed by the fusion protein, which engages to receptor(s) triggering a conformational change necessary to induce fusion between both membranes. This conformational change can occur in the plasma membrane at neutral pH or in the endosomal membranes upon endosome acidification. In the case of naked viruses, endosome acidification is needed to trigger conformational changes of the viral protein required in order to transiently destabilize the target membrane without compromising its overall integrity. [10][11][12] Virus entry is not a passive process, since productive entry, and downstream events rely on normal cellular processes including endocytosis (clathrin-mediated, clathrin-independent pathway, raft-dependent pathways, and macropinocytosis), vesicular trafficking, and membrane fusion, all of which involve dynamic membrane processes. [10,13] The fact that lipid interactions, including membrane envelopment, membrane fusion, and membrane remodeling are crucial for successful replication of many viruses triggered studies on compounds that either affect lipid biosynthesis,The viral entry consists of several sequential events that ensure the attachment of the virus to the host cell and the introduction of its genetic material for the continuation of the replication cycle. Both cellular an...

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Phosphatidylserine Vesicles Enable Efficient En Bloc Transmission of Enteroviruses

Cited by 410 publications

References 50 publications

Protein composition of the hepatitis A virus quasi-envelope

Protein composition of the hepatitis A virus quasi-envelope

Antiviral Strategies Against (Non‐polio) Picornaviruses

Role of Protein–Lipid Interactions in Viral Entry

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