In the extracellular environment, cell-free virions seek out naive host cells over long distances and between organisms. This is the primary mechanism of spread for most viruses. Here we provide evidence for an alternative pathway previously undescribed for orthomyxoviruses, whereby the spread of influenza A virus (IAV) infectious cores to neighboring cells can occur within intercellular connections. The formation of these connections requires actin dynamics and is enhanced by viral infection. Connected cells have contiguous membranes, and the core infectious viral machinery (RNP and polymerase) was present inside the intercellular connections. A live-cell movie of green fluorescent protein (GFP)-tagged NS1 of IAV shows viral protein moving from one cell to another through an intercellular connection. The movement of tagged protein was saltatory but overall traveled only in one direction. Infectious virus cores can move from one cell to another without budding and release of cell-free virions, as evidenced by the finding that whereas a neuraminidase inhibitor alone did not inhibit the development of IAV microplaques, the presence of a neuraminidase inhibitor together with drugs inhibiting actin dynamics or the microtubule stabilizer paclitaxel (originally named taxol) precluded microplaque formation. Similar results were also observed with parainfluenza virus 5 (PIV5), a paramyxovirus, when neutralizing antibody was used to block spread by cell-free virions. Intercellular spread of infectious core particles was unaffected or enhanced in the presence of nocodazole for IAV but inhibited for PIV5. The intercellular connections have a core of filamentous actin, which hints toward transport of virus particles through the use of a myosin motor. IMPORTANCE Here we describe a new method by which influenza A virus (IAV) spreads from cell to cell: IAV uses intracellular connections. The formation of these connections requires actin dynamics and is enhanced by viral infection and the absence of microtubules.Connected cells appeared to have contiguous membranes, and the core infectious viral machinery (RNP and polymerase) was present inside the intercellular connections. Infectious virus cores can move from one cell to another without budding and release of cell-free virions. Similar results were also observed with parainfluenza virus 5 (PIV5). Influenza A virus (IAV), a member of the Orthomyxoviridae, is an enveloped virus with a negative-strand segmented RNA genome. In virions, the eight RNA segments are decorated with the nucleocapsid protein (NP) and one copy of a heterotrimer of the RNA-dependent RNA polymerase complex consisting of PB1, PB2, and PA. The ribonucleoprotein (RNP) and polymerase complex are the minimal replicative machinery. The ribonucleoproteins are enclosed within a lipid envelope derived from the host cell plasma membrane. Underlying the bilayer is an internal coat of matrix protein (M1). Inserted through the lipid bilayer are the viral integral membrane proteins hemagglutinin (HA) and neurami...
Influenza virus assembles and buds at the infected-cell plasma membrane. This involves extrusion of the plasma membrane followed by scission of the bud, resulting in severing the nascent virion from its former host. The influenza virus M2 ion channel protein contains in its cytoplasmic tail a membrane-proximal amphipathic helix that facilitates the scission process and is also required for filamentous particle formation. Mutation of five conserved hydrophobic residues to alanines within the amphipathic helix (M2 five-point mutant, or 5PM) reduced scission and also filament formation, whereas single mutations had no apparent phenotype. Here, we show that any two of these five residues mutated together to alanines result in virus debilitated for growth and filament formation in a manner similar to 5PM. Growth kinetics of the M2 mutants are approximately 2 logs lower than the wild-type level, and plaque diameter was significantly reduced. When the 5PM and a representative double mutant (I51A-Y52A) were introduced into A/WSN/33 M2, a strain that produces spherical particles, similar debilitation in viral growth occurred. Electron microscopy showed that with the 5PM and the I51A-Y52A A/Udorn/72 and WSN viruses, scission failed, and emerging virus particles exhibited a "beads-on-a-string" morphology. The major spike glycoprotein hemagglutinin is localized within lipid rafts in virus-infected cells, whereas M2 is associated at the periphery of rafts. Mutant M2s were more widely dispersed, and their abundance at the raft periphery was reduced, suggesting that the M2 amphipathic helix is required for proper localization in the host membrane and that this has implications for budding and scission.
The final step in the egress of herpes simplex virus (HSV) virions requires virion-laden vesicles to bypass cortical actin and fuse with the plasma membrane, releasing virions into the extracellular space. Little is known about the host or viral proteins involved. In the current study, we noted that the conformation of myosin Va (myoVa), a protein known to be involved in melanosome and secretory granule trafficking to the plasma membrane in melanocytes and neuroendocrine cells, respectively, was altered by 4 h after infection with HSV-1 such that an N-terminal epitope expected to be masked in its inactive state was rendered immunoreactive. Wild-type myoVa localized throughout the cytoplasm and to a limited extent in the nuclei of HSV-infected cells. Two different dominant negative myoVa molecules containing cargo-binding domains but lacking the lever arms and actin-binding domains colocalized with markers of the trans-Golgi network (TGN). Expression of dominant negative myoVa isoforms reduced secretion of HSV-1 infectivity into the medium by 50 to 75%, reduced surface expression of glycoproteins B, M, and D, and increased intracellular virus infectivity to levels consistent with increased retention of virions in the cytoplasm. These data suggest that myoVa is activated during HSV-1 infection to help transport virion-and glycoprotein-laden vesicles from the TGN, through the cortical actin, to the plasma membrane. We cannot exclude a role for myoVa in promoting fusion of these vesicles with the inner surface of the plasma membrane. These data also indicate that myoVa is involved in exocytosis in human epithelial cells as well as other cell types.Herpes simplex virus (HSV) virions, like those of all herpesviruses, comprise a lipid envelope surrounding a layer of proteins called the tegument that covers the surface of the proteinaceous DNA-containing capsid. After assembly in the nucleus, herpes simplex virus nucleocapsids bud through the inner nuclear membrane to obtain an initial virion envelope. In the most widely accepted model of virion egress, the envelopes of nascent virions residing in the perinuclear space then fuse with the outer nuclear membrane, releasing the de-enveloped capsid into the cytoplasm (25). The now cytosolic capsid then buds into a membranous organelle in the cytoplasm to obtain its final envelope. The site of secondary envelopment where the final budding event occurs is believed to contain markers of the trans-Golgi network (TGN) (28) and would be expected to contain the full complement of virion envelope and tegument proteins. Cellular budding machinery would also be expected to be involved, such as that required for multivesicular body formation (1, 4). Other models of virion egress propose that nucleocapsids can exit the nucleus through an expanded nuclear pore (33, 34), or that the original virion envelope derived from the inner nuclear membrane is retained throughout egress (13). In the latter scenario, enveloped virions are incorporated into a vesicle derived from the outer nuclear me...
Actin is important for a variety of cellular processes, including uptake of extracellular material and intracellular transport. Several emerging lines of evidence indicate that herpesviruses exploit actin and actin-associated myosin motors for viral entry, intranuclear transport of capsids, and virion egress. The goal of this review is to explore these processes and to highlight potential future directions for this area of research.
Integral to the virulence of the intracellular bacterial pathogen Listeria monocytogenes is its metalloprotease (Mpl). Mpl regulates the activity and compartmentalization of the bacterial broad-range phospholipase C (PC-PLC). Mpl is secreted as a proprotein that undergoes intramolecular autocatalysis to release its catalytic domain. In related proteases, the propeptide serves as a folding catalyst and can act either in cis or in trans. Propeptides can also influence protein compartmentalization and intracellular trafficking or decrease folding kinetics. In this study, we aimed to determine the role of the Mpl propeptide by monitoring the behavior of Mpl synthesized in the absence of its propeptide (Mpl⌬pro) and of two Mpl single-site mutants with unstable propeptides: Mpl(H75V) and Mpl(H95L). We observed that all three Mpl mutants mediate PC-PLC activation when bacteria are grown on semisolid medium, but to a lesser extent than wild-type Mpl, indicating that, although not essential, the propeptide enhances the production of active Mpl. However, the mutant proteins were not functional in infected cells, as determined by monitoring PC-PLC maturation and compartmentalization. This defect could not be rescued by providing the propeptide in trans to the mpl⌬pro mutant. We tested the compartmentalization of Mpl during intracellular infection and observed that the mutant Mpl species were aberrantly secreted in the cytosol of infected cells. These data indicated that the propeptide of Mpl serves to maintain bacterium-associated Mpl and that this localization is essential to the function of Mpl during intracellular infection.
Russia’s 2014 annexation of Crimea and the subsequent deterioration in its relations with the West have led many analysts to adopt a narrow view of Vladimir Putin’s foreign policy motivations, chalking them up to old-school geopolitics. This paper makes the case that the traditional structural explanations for Russian foreign policy that are dominant within the discipline of international relations do not adequately consider the influence of identity in Putin’s emerging foreign policy narrative. Putin’s narrative is shaped by, and shapes, a discourse about cultural and historical ties with Russian borderlands, as well as by the cultural and security vulnerabilities generated by the West’s treatment of Russia, evidenced by the expansion of the North Atlantic Treaty Organization (NATO). This discourse has underscored a more militant foreign policy turn under Putin in which he is prepared to protect and defend Russia’s interests at high cost; Russia’s actions in Crimea exemplify this. This connection between identity and foreign policy in Putin’s Russia demands attention if we hope to gain a better grasp of Russian foreign policy under his leadership.
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