Microtubule Regulation and Function during Virus Infection

Naghavi, Mojgan H.; Walsh, Derek

doi:10.1128/jvi.00538-17

Cited by 105 publications

(102 citation statements)

References 149 publications

(155 reference statements)

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“…Rapid intracytosolic cargo transport often occurs along microtubules (MTs) using dynein motor complexes on minus‐end MTs toward the nucleus or kinesin motor complexes on plus‐end MTs to the cell periphery . AdC2 or AdC5 was shown under EM to bind MTs in the cytosol as membrane‐free particles .…”

Section: From the Cell Surface To The Nuclear Porementioning

confidence: 99%

Imaging the adenovirus infection cycle

Pied

Wodrich

2019

FEBS Letters

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Edited by Urs GreberIncoming adenoviruses seize control of cytosolic transport mechanisms to relocate their genome from the cell periphery to specialized sites in the nucleoplasm. The nucleus is the site for viral gene expression, genome replication, and the production of progeny for the next round of infection. By taking control of the cell, adenoviruses also suppress cell-autonomous immunity responses. To succeed in their production cycle, adenoviruses rely on wellcoordinated steps, facilitated by interactions between viral proteins and cellular factors. Interactions between virus and host can impose remarkable morphological changes in the infected cell. Imaging adenoviruses has tremendously influenced how we delineate individual steps in the viral life cycle, because it allowed the development of specific optical markers to label these morphological changes in space and time. As technology advances, innovative imaging techniques and novel tools for specimen labeling keep uncovering previously unseen facets of adenovirus biology emphasizing why imaging adenoviruses is as attractive today as it was in the past. This review will summarize past achievements and present developments in adenovirus imaging centered on fluorescence microscopy approaches.Adenoviruses (Ads) are nonenveloped icosahedral viruses with a diameter of~90 nm with slight structural differences between genotypes. The majority of the Ad capsid shell is composed of 240 hexon trimers, and each of the 12 vertices of the icosahedron is occupied by a penton. Pentons are involved in cell attachment and receptor recognition and are composed of the pentameric penton base from which the trimeric fiber molecule extends. Minor capsid proteins IIIa, VI, VIII, and IX are embedded in the capsid and contribute to capsid stability. Protein VI is located at the inner surface of the capsid, and biochemical data suggest that it may connect the capsid to the core containing the viral genome via protein V. The genome is ã 36-kb double-stranded linear DNA molecule with the terminal protein (TP) covalently bound to each 5 0end. Adenovirus genomes are highly condensed and organized into chromatin by several hundred copies of Abbreviations ADP, adenovirus death protein

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Section: From the Cell Surface To The Nuclear Porementioning

confidence: 99%

Imaging the adenovirus infection cycle

Pied

Wodrich

2019

FEBS Letters

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“…Association of dynactin with the incoming alphaherpesvirus capsid [64,68,69] is likely to contribute to the processivity of dynein-mediated retrograde motion [66,71], but it may also mediate attachment of capsids to the plus ends of MTs by connecting them to the EB1/CLIP-170 (end-binding protein 1/cytoplasmic linker protein 170) complex [72,73]. EB1 is a +TIP (plus-end-tracking protein) that recognizes the growing ends of dynamic MTs and recruits other regulatory +TIPS to them [74,75].…”

Section: Recruitment Of Dynein and Dynactin By The Inner Tegument Promentioning

confidence: 99%

Microtubule-Dependent Trafficking of Alphaherpesviruses in the Nervous System: The Ins and Outs

Diwaker

Wilson

2019

Viruses

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The Alphaherpesvirinae include the neurotropic pathogens herpes simplex virus and varicella zoster virus of humans and pseudorabies virus of swine. These viruses establish lifelong latency in the nuclei of peripheral ganglia, but utilize the peripheral tissues those neurons innervate for productive replication, spread, and transmission. Delivery of virions from replicative pools to the sites of latency requires microtubule-directed retrograde axonal transport from the nerve terminus to the cell body of the sensory neuron. As a corollary, during reactivation newly assembled virions must travel along axonal microtubules in the anterograde direction to return to the nerve terminus and infect peripheral tissues, completing the cycle. Neurotropic alphaherpesviruses can therefore exploit neuronal microtubules and motors for long distance axonal transport, and alternate between periods of sustained plus end- and minus end-directed motion at different stages of their infectious cycle. This review summarizes our current understanding of the molecular details by which this is achieved.

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“…Viruses must engage bidirectional cellular transport mechanisms for completing their whole life cycle, and many viruses require microtubules (MTs) during cell entry for efficient nuclear targeting or the cytosolic transport of naked viral particles [70][71][72]. In BFV, co-localization of MTs and assembling viral particles was clearly observed in BFV infected cells, which implied that BFV particles or assembly intermediates may transport along the cellular MTs to the cellular membrane to ultimately egress from the host cell.…”

Section: Function and Localization Of Gagmentioning

confidence: 99%

Bovine Foamy Virus: Shared and Unique Molecular Features In Vitro and In Vivo

Materniak-Kornas

Tan

Heit-Mondrzyk

et al. 2019

Viruses

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The retroviral subfamily of Spumaretrovirinae consists of five genera of foamy (spuma) viruses (FVs) that are endemic in some mammalian hosts. Closely related species may be susceptible to the same or highly related FVs. FVs are not known to induce overt disease and thus do not pose medical problems to humans and livestock or companion animals. A robust lab animal model is not available or is a lab animal a natural host of a FV. Due to this, research is limited and often focused on the simian FVs with their well-established zoonotic potential. The authors of this review and their groups have conducted several studies on bovine FV (BFV) in the past with the intention of (i) exploring the risk of zoonotic infection via beef and raw cattle products, (ii) studying a co-factorial role of BFV in different cattle diseases with unclear etiology, (iii) exploring unique features of FV molecular biology and replication strategies in non-simian FVs, and (iv) conducting animal studies and functional virology in BFV-infected calves as a model for corresponding studies in primates or small lab animals. These studies gained new insights into FV-host interactions, mechanisms of gene expression, and transcriptional regulation, including miRNA biology, host-directed restriction of FV replication, spread and distribution in the infected animal, and at the population level. The current review attempts to summarize these findings in BFV and tries to connect them to findings from other FVs.

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Microtubule Regulation and Function during Virus Infection

Cited by 105 publications

References 149 publications

Imaging the adenovirus infection cycle

Imaging the adenovirus infection cycle

Microtubule-Dependent Trafficking of Alphaherpesviruses in the Nervous System: The Ins and Outs

Bovine Foamy Virus: Shared and Unique Molecular Features In Vitro and In Vivo

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