Your search keyword '"Richard J. Sugrue"' showing total 4 results

1. Evidence for a biphasic mode of respiratory syncytial virus transmission in permissive HEp2 cell monolayers

Author

Richard J. Sugrue, Tra Nguyen Huong, Laxmi Iyer Ravi, Boon Huan Tan, and School of Biological Sciences

Subjects

0301 basic medicine, Cell Membrane Permeability, viruses, 030106 microbiology, DNA Fragmentation, Respiratory Syncytial Virus Infections, Biology, Virus Replication, Virus, Cell Line, 03 medical and health sciences, Multiplicity of infection, Virology, medicine, Animals, Humans, Fragmentation (cell biology), Cell damage, Cells, Cultured, Infectivity, Virus quantification, Viral culture, Research, Biological Transport, Biological Sciences, medicine.disease, Actins, 030104 developmental biology, Infectious Diseases, Viral replication, Respiratory Syncytial Virus, Human, Signal Transduction

Abstract

Background During respiratory syncytial virus (RSV) infection filamentous virus particles are formed on the cell surface. Although the virus infectivity remains cell-associated, low levels of cell-free virus is detected during advanced infection. It is currently unclear if this cell-free virus infectivity is due to a low-efficiency specific cell-release mechanism, or if it arises due to mechanical breakage following virus-induced cell damage at the advanced stage of infection. Understanding the origin of this cell-free virus is a prerequisite for understanding the mechanism of RSV transmission in permissive cells. In this study we describe a detailed examination of RSV transmission in permissive HEp2 cell monolayers. Methods HEp2 cell monolayers were infected with RSV using a multiplicity of infection of 0.0002, and the course of infection monitored over 5 days. The progression of the virus infection within the cell monolayers was performed using bright-field microscopy to visualise the cell monolayer and immunofluorescence microscopy to detect virus-infected cells. The cell-associated and cell-free virus infectivity were determined by virus plaque assay, and the virus-induced cell cytotoxicity determined by measuring cell membrane permeability and cellular DNA fragmentation. Results At 2 days-post infection (dpi), large clusters of virus-infected cells could be detected indicating localised transmission in the cell monolayer, and during this stage we failed to detect either cell-free virus or cell cytotoxicity. At 3 dpi the presence of much larger infected cell clusters correlated with the begining of virus-induced changes in cell permeability. The presence of cell-free virus correlated with continued increase in cell permeability and cytotoxicity at 4 and 5 dpi. At 5 dpi extensive cell damage, syncytial formation, and increased cellular DNA fragmentation was noted. However, even at 5 dpi the cell-free virus constituted less than 1 % of the total virus infectivity. Conclusions Our data supports a model of RSV transmission that initially involves the localised cell-to-cell spread of virus particles within the HEp2 cell monolayer. However, low levels of cell free-virus infectivity was observed at the advanced stages of infection, which correlated with a general loss in cell monolayer integrity due to virus-induced cytotoxicity. Electronic supplementary material The online version of this article (doi:10.1186/s12985-016-0467-9) contains supplementary material, which is available to authorized users.

Published

2016

2. Evidence for the interaction of the human metapneumovirus G and F proteins during virus-like particle formation

Author

Pui San Wong, T. C. Ayi, Nancy W S Tee, Boon Huan Tan, Richard J. Sugrue, Muhammad Raihan Jumat, Liat Hui Loo, and Y. Fu

Subjects

Virosomes, G protein, viruses, Molecular Sequence Data, Gene Expression, HMPV G protein, Plasma protein binding, Virus, Cell Line, HMPV F protein, Protein–protein interaction, Viral Proteins, Recombinant expression, Human metapneumovirus, Virus-like particle, Virus morphology, Virology, Centrifugation, Density Gradient, Humans, Child, Glycoproteins, biology, Research, Protein interactions, virus diseases, Sequence Analysis, DNA, biology.organism_classification, Molecular biology, Recombinant Proteins, respiratory tract diseases, Microscopy, Electron, Infectious Diseases, Viral replication, Child, Preschool, RNA, Viral, Metapneumovirus, Viral Fusion Proteins, Protein Binding

Abstract

Background Human metapneumovirus (HMPV) is now a major cause of lower respiratory infection in children. Although primary isolation of HMPV has been achieved in several different cell lines, the low level of virus replication and the subsequent recovery of low levels of infectious HMPV have hampered biochemical studies on the virus. These experimental methodologies usually require higher levels of biological material that can be achieved following HMPV infection. In this study we demonstrate that expression of the HMPV F, G and M proteins in mammalian cells leads to HMPV virus-like particles (VLP) formation. This experimental strategy will serve as a model system to allow the process of HMPV virus assembly to be examined. Methods The HMPV F, G and M proteins were expressed in mammalian cell lines. Protein cross-linking studies, sucrose gradient centrifugation and in situ imaging was used to examine interactions between the virus proteins. VLP formation was examined using sucrose density gradient centrifugation and electron microscopy analysis. Results Analysis of cells co-expressing the F, G and M proteins demonstrated that these proteins interacted. Furthermore, in cells co-expression the three HMPV proteins the formation VLPs was observed. Image analysis revealed the VLPs had a similar morphology to the filamentous virus morphology that we observed on HMPV-infected cells. The capacity of each protein to initiate VLP formation was examined using a VLP formation assay. Individual expression of each virus protein showed that the G protein was able to form VLPs in the absence of the other virus proteins. Furthermore, co-expression of the G protein with either the M or F proteins facilitated their incorporation into the VLP fraction. Conclusion Co-expression of the F, G and M proteins leads to the formation of VLPs, and that incorporation of the F and M proteins into VLPs is facilitated by their interaction with the G protein. Our data suggests that the G protein plays a central role in VLP formation, and further suggests that the G protein may also play a role in the recruitment of the F and M proteins to sites of virus particle formation during HMPV infection.

Published

2013

3. Whole genome characterization of non-tissue culture adapted HRSV strains in severely infected children

Author

Martin L. Hibberd, Eric A. F. Simões, Laxmi R. Iyer, Rajni Kumaria, and Richard J. Sugrue

Subjects

Sequence analysis, Molecular Sequence Data, Mutation, Missense, Genome, Viral, Respiratory Syncytial Virus Infections, Biology, medicine.disease_cause, Genome, Virus, lcsh:Infectious and parasitic diseases, 03 medical and health sciences, symbols.namesake, Tissue culture, Viral Proteins, HRSV A type severe clinical strains, Virology, Genetic variation, medicine, Human respiratory syncytial virus, Humans, Whole genome sequence, Protein analysis, lcsh:RC109-216, Prospective Studies, Gene, 030304 developmental biology, Sequence Deletion, Genetics, Sanger sequencing, 0303 health sciences, Mutation, Phylogenetic analysis, 030306 microbiology, Research, Genetic Variation, Infant, Sequence Analysis, DNA, 3. Good health, Nasal Mucosa, Infectious Diseases, Respiratory Syncytial Virus, Human, symbols, RNA, Viral

Abstract

Background Human respiratory syncytial virus (HRSV) is the most important virus causing lower respiratory infection in young children. The complete genetic characterization of RSV clinical strains is a prerequisite for understanding HRSV infection in the clinical context. Current information about the genetic structure of the HRSV genome has largely been obtained using tissue culture adapted viruses. During tissue culture adaptation genetic changes can be introduced into the virus genome, which may obscure subtle variations in the genetic structure of different RSV strains. Methods In this study we describe a novel Sanger sequencing strategy which allowed the complete genetic characterisation of 14 clinical HRSV strains. The viruses were sequenced directly in the nasal washes of severely hospitalized children, and without prior passage of the viruses in tissue culture. Results The analysis of nucleotide sequences suggested that vRNA length is a variable factor among primary strains, while the phylogenetic analysis suggests selective pressure for change. The G gene showed the greatest sequence variation (2-6.4%), while small hydrophobic protein and matrix genes were completely conserved across all clinical strains studied. A number of sequence changes in the F, L, M2-1 and M2-2 genes were observed that have not been described in laboratory isolates. The gene junction regions showed more sequence variability, and in particular the intergenic regions showed a highest level of sequence variation. Although the clinical strains grew slower than the HRSVA2 virus isolate in tissue culture, the HRSVA2 isolate and clinical strains formed similar virus structures such as virus filaments and inclusion bodies in infected cells; supporting the clinical relevance of these virus structures. Conclusion This is the first report to describe the complete genetic characterization of HRSV clinical strains that have been sequenced directly from clinical material. The presence of novel substitutions and deletions in the vRNA of clinical strains emphasize the importance of genomic characterization of non-tissue culture adapted primary strains.

Published

2011

4. Evidence for the interaction of the human metapneumovirus G and F proteins during virus-like particle formation.

Author

Liat Hui Loo, Muhammad Raihan Jumat, Yi Fu, Teck Choon Ayi, Pui San Wong, Tee, Nancy W. S., Boon Huan Tan, and Richard J. Sugrue

Subjects

VIRUS-like particles, CELL culture, RESPIRATORY infections in children, G proteins, ELECTRON microscopy

Abstract

Background: Human metapneumovirus (HMPV) is now a major cause of lower respiratory infection in children. Although primary isolation of HMPV has been achieved in several different cell lines, the low level of virus replication and the subsequent recovery of low levels of infectious HMPV have hampered biochemical studies on the virus. These experimental methodologies usually require higher levels of biological material that can be achieved following HMPV infection. In this study we demonstrate that expression of the HMPV F, G and M proteins in mammalian cells leads to HMPV virus-like particles (VLP) formation. This experimental strategy will serve as a model system to allow the process of HMPV virus assembly to be examined. Methods: The HMPV F, G and M proteins were expressed in mammalian cell lines. Protein cross-linking studies, sucrose gradient centrifugation and in situ imaging was used to examine interactions between the virus proteins. VLP formation was examined using sucrose density gradient centrifugation and electron microscopy analysis. Results: Analysis of cells co-expressing the F, G and M proteins demonstrated that these proteins interacted. Furthermore, in cells co-expression the three HMPV proteins the formation VLPs was observed. Image analysis revealed the VLPs had a similar morphology to the filamentous virus morphology that we observed on HMPV-infected cells. The capacity of each protein to initiate VLP formation was examined using a VLP formation assay. Individual expression of each virus protein showed that the G protein was able to form VLPs in the absence of the other virus proteins. Furthermore, co-expression of the G protein with either the M or F proteins facilitated their incorporation into the VLP fraction. Conclusion: Co-expression of the F, G and M proteins leads to the formation of VLPs, and that incorporation of the F and M proteins into VLPs is facilitated by their interaction with the G protein. Our data suggests that the G protein plays a central role in VLP formation, and further suggests that the G protein may also play a role in the recruitment of the F and M proteins to sites of virus particle formation during HMPV infection [ABSTRACT FROM AUTHOR]

Published

2013