Your search keyword '"Cytoskeleton virology"' showing total 3 results

1. Rotavirus replication is correlated with S/G2 interphase arrest of the host cell cycle.

Author

Glück S, Buttafuoco A, Meier AF, Arnoldi F, Vogt B, Schraner EM, Ackermann M, and Eichwald C

Subjects

Animals, Cyclin B1 metabolism, Cytoskeleton metabolism, Cytoskeleton virology, Dogs, HEK293 Cells, Humans, Kinesins metabolism, Macaca mulatta, Madin Darby Canine Kidney Cells, Viral Proteins metabolism, G2 Phase Cell Cycle Checkpoints, Rotavirus physiology, S Phase Cell Cycle Checkpoints, Signal Transduction, Virus Replication physiology

Abstract

In infected cells rotavirus (RV) replicates in viroplasms, cytosolic structures that require a stabilized microtubule (MT) network for their assembly, maintenance of the structure and perinuclear localization. Therefore, we hypothesized that RV could interfere with the MT-breakdown that takes place in mitosis during cell division. Using synchronized RV-permissive cells, we show that RV infection arrests the cell cycle in S/G2 phase, thus favoring replication by improving viroplasms formation, viral protein translation, and viral assembly. The arrest in S/G2 phase is independent of the host or viral strain and relies on active RV replication. RV infection causes cyclin B1 down-regulation, consistent with blocking entry into mitosis. With the aid of chemical inhibitors, the cytoskeleton network was linked to specific signaling pathways of the RV-induced cell cycle arrest. We found that upon RV infection Eg5 kinesin was delocalized from the pericentriolar region to the viroplasms. We used a MA104-Fucci system to identify three RV proteins (NSP3, NSP5, and VP2) involved in cell cycle arrest in the S-phase. Our data indicate that there is a strong correlation between the cell cycle arrest and RV replication.

Published

2017

2. Avibirnavirus VP4 Protein Is a Phosphoprotein and Partially Contributes to the Cleavage of Intermediate Precursor VP4-VP3 Polyprotein.

Author

Wang S, Hu B, Si W, Jia L, Zheng X, and Zhou J

Subjects

Amino Acid Motifs, Animals, Antibodies, Monoclonal chemistry, Cell Line, Chickens, Cytoskeleton virology, Epitope Mapping, HEK293 Cells, Humans, Infectious bursal disease virus genetics, Infectious bursal disease virus metabolism, Isoelectric Point, Molecular Sequence Data, Mutagenesis, Site-Directed, Phosphoproteins metabolism, Phosphorylation, Protein Precursors metabolism, Proteolysis, Viral Structural Proteins metabolism, Fibroblasts virology, Gene Expression Regulation, Viral, Phosphoproteins genetics, Protein Precursors genetics, Viral Structural Proteins genetics

Abstract

Birnavirus-encoded viral protein 4 (VP4) utilizes a Ser/Lys catalytic dyad mechanism to process polyprotein. Here three phosphorylated amino acid residues Ser538, Tyr611 and Thr674 within the VP4 protein of the infectious bursal disease virus (IBDV), a member of the genus Avibirnavirus of the family Birnaviridae, were identified by mass spectrometry. Anti-VP4 monoclonal antibodies finely mapping to phosphorylated (p)Ser538 and the epitope motif 530PVVDGIL536 were generated and verified. Proteomic analysis showed that in IBDV-infected cells the VP4 was distributed mainly in the cytoskeletal fraction and existed with different isoelectric points and several phosphorylation modifications. Phosphorylation of VP4 did not influence the aggregation of VP4 molecules. The proteolytic activity analysis verified that the pTyr611 and pThr674 sites within VP4 are involved in the cleavage of viral intermediate precursor VP4-VP3. This study demonstrates that IBDV-encoded VP4 protein is a unique phosphoprotein and that phosphorylation of Tyr611 and Thr674 of VP4 affects its serine-protease activity.

Published

2015

3. Tick-borne encephalitis virus replication, intracellular trafficking, and pathogenicity in human intestinal Caco-2 cell monolayers.

Author

Yu C, Achazi K, Möller L, Schulzke JD, Niedrig M, and Bücker R

Subjects

Biological Transport, Caco-2 Cells, Cytoskeleton virology, Encephalitis Viruses, Tick-Borne metabolism, Humans, Intestines ultrastructure, Virulence, Virus Internalization, Encephalitis Viruses, Tick-Borne pathogenicity, Encephalitis Viruses, Tick-Borne physiology, Intestines cytology, Intestines virology, Intracellular Space virology, Pinocytosis, Virus Replication

Abstract

Tick-borne encephalitis virus (TBEV) is one of the most important vector-borne viruses in Europe and Asia. Its transmission mainly occurs by the bite of an infected tick. However, consuming milk products from infected livestock animals caused TBEV cases. To better understand TBEV transmission via the alimentary route, we studied viral infection of human intestinal epithelial cells. Caco-2 cells were used to investigate pathological effects of TBEV infection. TBEV-infected Caco-2 monolayers showed morphological changes including cytoskeleton rearrangements and cytoplasmic vacuolization. Ultrastructural analysis revealed dilatation of the rough endoplasmic reticulum and further enlargement to TBEV containing caverns. Caco-2 monolayers maintained an intact epithelial barrier with stable transepithelial electrical resistance (TER) during early stage of infection. Concomitantly, viruses were detected in the basolateral medium, implying a transcytosis pathway. When Caco-2 cells were pre-treated with inhibitors of cellular pathways of endocytosis TBEV cell entry was efficiently blocked, suggesting that actin filaments (Cytochalasin) and microtubules (Nocodazole) are important for PI3K-dependent (LY294002) virus endocytosis. Moreover, experimental fluid uptake assay showed increased intracellular accumulation of FITC-dextran containing vesicles. Immunofluorescence microscopy revealed co-localization of TBEV with early endosome antigen-1 (EEA1) as well as with sorting nexin-5 (SNX5), pointing to macropinocytosis as trafficking mechanism. In the late phase of infection, further evidence was found for translocation of virus via the paracellular pathway. Five days after infection TER was slightly decreased. Epithelial barrier integrity was impaired due to increased epithelial apoptosis, leading to passive viral translocation. These findings illuminate pathomechanisms in TBEV infection of human intestinal epithelial cells and viral transmission via the alimentary route.

Published

2014