Cellular Mechanisms of Alpha Herpesvirus Egress: Live Cell Fluorescence Microscopy of Pseudorabies Virus Exocytosis

Hogue, Ian B.; Bosse, Jens B.; Hu, Jiun-Ruey; Thiberge, Stephan Y.; Enquist, Lynn W.

doi:10.1371/journal.ppat.1004535

Cited by 75 publications

(145 citation statements)

References 59 publications

(82 reference statements)

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“…1). From the time of assembly and egress of a newly synthesized virion to its entry into a new target cell, a single enveloped HSV particle may encounter multiple acidic-pH environments (2,31). We next assessed the effect of multiple low-pH exposures on HSV-1 infectivity.…”

Section: Figmentioning

confidence: 99%

Mildly Acidic pH Triggers an Irreversible Conformational Change in the Fusion Domain of Herpes Simplex Virus 1 Glycoprotein B and Inactivation of Viral Entry

Weed

Pritchard

Gonzalez

et al. 2017

J Virol

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Herpes simplex virus (HSV) entry into a subset of cells requires endocytosis and endosomal low pH. Preexposure of isolated virions to mildly acidic pH of 5 to 6 partially inactivates HSV infectivity in an irreversible manner. Acid inactivation is a hallmark of viruses that enter via low-pH pathways; this occurs by pretriggering conformational changes essential for fusion. The target and mechanism(s) of low-pH inactivation of HSV are unclear. Here, low-pH-treated HSV-1 was defective in fusion activity and yet retained normal levels of attachment to cell surface heparan sulfate and binding to nectin-1 receptor. Low-pH-triggered conformational changes in gB reported to date are reversible, despite irreversible low-pH inactivation. gB conformational changes and their reversibility were measured by antigenic analysis with a panel of monoclonal antibodies and by detecting changes in oligomeric conformation. Three-hour treatment of HSV-1 virions with pH 5 or multiple sequential treatments at pH 5 followed by neutral pH caused an irreversible Ͼ2.5 log infectivity reduction. While changes in several gB antigenic sites were reversible, alteration of the H126 epitope was irreversible. gB oligomeric conformational change remained reversible under all conditions tested. Altogether, our results reveal that oligomeric alterations and fusion domain changes represent distinct conformational changes in gB, and the latter correlates with irreversible low-pH inactivation of HSV. We propose that conformational change in the gB fusion domain is important for activation of membrane fusion during viral entry and that in the absence of a host target membrane, this change results in irreversible inactivation of virions.IMPORTANCE HSV-1 is an important pathogen with a high seroprevalence throughout the human population. HSV infects cells via multiple pathways, including a low-pH route into epithelial cells, the primary portal into the host. HSV is inactivated by low-pH preexposure, and gB, a class III fusion protein, undergoes reversible conformational changes in response to low-pH exposure. Here, we show that low-pH inactivation of HSV is irreversible and due to a defect in virion fusion activity. We identified an irreversible change in the fusion domain of gB following multiple sequential low-pH exposures or following prolonged low-pH treatment. This change appears to be separable from the alteration in gB quaternary structure. Together, the results are consistent with a model by which low pH can have an activating or inactivating effect on HSV depending on the presence of a target membrane.KEYWORDS conformational changes, glycoprotein B, herpes simplex viruses, herpesviruses, inactivation, low pH, membrane fusion

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Section: Figmentioning

confidence: 99%

Mildly Acidic pH Triggers an Irreversible Conformational Change in the Fusion Domain of Herpes Simplex Virus 1 Glycoprotein B and Inactivation of Viral Entry

Weed

Pritchard

Gonzalez

et al. 2017

J Virol

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“…Finally, the vesicle containing the mature enveloped particle fuses with the plasma membrane, releasing the mature virion in an exocytosis-like event. [1][2][3] In the last 20 y or so it became very clear that both during entry as well as exit, herpesvirus particles use microtubule-associated, motor-dependent transport to cross the cytoplasmic space. [4][5][6] However much less is known of how newly formed and packaged capsids cross the nuclear space to the reach the inner nuclear membrane for egress.…”

Section: Introductionmentioning

confidence: 99%

The diffusive way out: Herpesviruses remodel the host nucleus, enabling capsids to access the inner nuclear membrane

Bosse

Enquist

2016

Nucleus

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Herpesviruses are large DNA viruses that utilize the host nucleus for genome replication as well as capsid assembly. After maturation, these 125 nm large capsid assemblies must cross the nucleoplasm to engage the nuclear envelope and bud into the cytoplasm. Here we summarize our recent findings how this motility is facilitated. We suggest that herpesvirus induced nuclear remodeling allows capsids to move by diffusion in the nucleus and not by motor-dependent transport.

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“…Transsynaptic viral labeling such as pseudorabies virus (PRV) (Lee et al, 2014) and wheat germ agglutinin (WGA) expressing vectors (Fujimoto et al, 2012) can be used to trace the entire circuit, but alternate routes of viral transmission should be considered when interpreting data from incomplete injuries. Although the available data supports the hypothesis that both PRV and WGA are transferred at active synaptic connections, many of those studies have been conducted in vitro (Hogue et al, 2014) or intact CNS (Ohashi et al, 2011) rather than a relay model of SCI repair. The release of vesicles from growth cones (Sabo and McAllister, 2003; Tojima et al, 2007), or the establishment and retraction of functional synapses within a relay could lead to labeling of neurons without permanent synaptic connections.…”

Section: Introductionmentioning

confidence: 99%

Repair of spinal cord injury with neuronal relays: From fetal grafts to neural stem cells

Bonner

Steward

2015

Brain Research

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Spinal cord injury (SCI) disrupts the long axonal tracts of the spinal cord leading to devastating loss of function. Cell transplantation in the injured spinal cord has the potential to lead to recovery after SCI via a variety of mechanisms. One such strategy is the formation of neuronal relays between injured long tract axons and denervated neurons. The idea of creating a neuronal relay was first proposed over 25 years ago when fetal tissue was first successfully transplanted into the injured rodent spinal cord. Advances in labeling of grafted cells and the development of neural stem cell culturing techniques have improved the ability to create and refine such relays. Several recent studies have examined the ability to create a novel neuronal circuit between injured axons and denervated targets. This approach is an alternative to long-distance regeneration of damaged axons that may provide a meaningful degree of recovery without direct recreation of lost pathways. This brief review will examine the contribution of fetal grafting to current advances in neuronal grafting. Of particular interest will be the ability of transplanted neurons derived from fetal grafts, neural precursor cells and neural stem cells to reconnect long distance motor and sensory pathways of the injured spinal cord.

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Cellular Mechanisms of Alpha Herpesvirus Egress: Live Cell Fluorescence Microscopy of Pseudorabies Virus Exocytosis

Cited by 75 publications

References 59 publications

Mildly Acidic pH Triggers an Irreversible Conformational Change in the Fusion Domain of Herpes Simplex Virus 1 Glycoprotein B and Inactivation of Viral Entry

Mildly Acidic pH Triggers an Irreversible Conformational Change in the Fusion Domain of Herpes Simplex Virus 1 Glycoprotein B and Inactivation of Viral Entry

The diffusive way out: Herpesviruses remodel the host nucleus, enabling capsids to access the inner nuclear membrane

Repair of spinal cord injury with neuronal relays: From fetal grafts to neural stem cells

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