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13 results on '"Weekes, Michael P."'

1. Strain-Dependent Restriction of Human Cytomegalovirus by Zinc Finger Antiviral Proteins

Author

Lista, Maria Jose, primary, Witney, Adam A., additional, Nichols, Jenna, additional, Davison, Andrew J., additional, Wilson, Harry, additional, Latham, Katie A., additional, Ravenhill, Benjamin J., additional, Nightingale, Katie, additional, Stanton, Richard J., additional, Weekes, Michael P., additional, Neil, Stuart J. D., additional, Swanson, Chad M., additional, and Strang, Blair L., additional

Published
2023
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2. Human cytomegalovirus RNA2.7 is required for upregulating multiple cellular genes to promote cell motility and viral spread late in lytic infection

Author

Lau, Betty, primary, Kerr, Karen, additional, Camiolo, Salvatore, additional, Nightingale, Katie, additional, Gu, Quan, additional, Antrobus, Robin, additional, Suárez, Nicolás M., additional, Loney, Colin, additional, Stanton, Richard J., additional, Weekes, Michael P., additional, and Davison, Andrew J., additional

Published
2021
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4. Genetic Evidence for Erythrocyte Receptor Glycophorin B Expression Levels Defining a Dominant Plasmodium falciparum Invasion Pathway into Human Erythrocytes

Author

Dankwa, Selasi, Chaand, Mudit, Kanjee, Usheer, Jiang, Rays HY, Nobre, Luis V, Goldberg, Jonathan M, Bei, Amy K, Moechtar, Mischka A, Grüring, Christof, Ahouidi, Ambroise D, Ndiaye, Daouda, Dieye, Tandakha N, Mboup, Souleymane, Weekes, Michael P, Duraisingh, Manoj T, Weekes, Michael [0000-0003-3196-5545], and Apollo - University of Cambridge Repository

Subjects
cultured erythrocyte, Proteomics, Erythrocytes, Plasmodium falciparum, malaria, transcriptional variation, Computational Biology, Receptors, Cell Surface, Ligands, Molecular Pathogenesis, glycophorin, parasitic diseases, Humans, Glycophorins, host cell invasion, red blood cells, Protein Binding
Abstract

Plasmodium falciparum, the parasite that causes the deadliest form of malaria, has evolved multiple proteins known as invasion ligands that bind to specific erythrocyte receptors to facilitate invasion of human erythrocytes. The EBA-175/glycophorin A (GPA) and Rh5/basigin ligand-receptor interactions, referred to as invasion pathways, have been the subject of intense study. In this study, we focused on the less-characterized sialic acid-containing receptors glycophorin B (GPB) and glycophorin C (GPC). Through bioinformatic analysis, we identified extensive variation in glycophorin B (GYPB) transcript levels in individuals from Benin, suggesting selection from malaria pressure. To elucidate the importance of the GPB and GPC receptors relative to the well-described EBA-175/GPA invasion pathway, we used an ex vivo erythrocyte culture system to decrease expression of GPA, GPB, or GPC via lentiviral short hairpin RNA transduction of erythroid progenitor cells, with global surface proteomic profiling. We assessed the efficiency of parasite invasion into knockdown cells using a panel of wild-type P. falciparum laboratory strains and invasion ligand knockout lines, as well as P. falciparum Senegalese clinical isolates and a short-term-culture-adapted strain. For this, we optimized an invasion assay suitable for use with small numbers of erythrocytes. We found that all laboratory strains and the majority of field strains tested were dependent on GPB expression level for invasion. The collective data suggest that the GPA and GPB receptors are of greater importance than the GPC receptor, supporting a hierarchy of erythrocyte receptor usage in P. falciparum.

Published
2017

5. Role of the B Allele of Influenza A Virus Segment 8 in Setting Mammalian Host Range and Pathogenicity

Author

Turnbull, Matthew L, Wise, Helen M, Nicol, Marlynne Q, Smith, Nikki, Dunfee, Rebecca L, Beard, Philippa M, Jagger, Brett W, Ligertwood, Yvonne, Hardisty, Gareth R, Xiao, Haixia, Benton, Donald J, Coburn, Alice M, Paulo, Joao A, Gygi, Steven P, McCauley, John W, Taubenberger, Jeffery K, Lycett, Samantha J, Weekes, Michael P, Dutia, Bernadette M, Digard, Paul, Weekes, Michael [0000-0003-3196-5545], and Apollo - University of Cambridge Repository

Subjects
Mammals, Mice, Inbred BALB C, Virulence, viruses, Influenza A Virus, H3N2 Subtype, Virus Replication, Host Specificity, Cell Line, Madin Darby Canine Kidney Cells, Birds, Mice, Viral Proteins, Dogs, HEK293 Cells, Influenza A Virus, H1N1 Subtype, Orthomyxoviridae Infections, A549 Cells, Cell Line, Tumor, Influenza in Birds, Influenza, Human, Animals, Humans, Alleles, Phylogeny, Reassortant Viruses
Abstract

UNLABELLED: Two alleles of segment 8 (NS) circulate in nonchiropteran influenza A viruses. The A allele is found in avian and mammalian viruses, but the B allele is viewed as being almost exclusively found in avian viruses. This might reflect the fact that one or both of its encoded proteins (NS1 and NEP) are maladapted for replication in mammalian hosts. To test this, a number of clade A and B avian virus-derived NS segments were introduced into human H1N1 and H3N2 viruses. In no case was the peak virus titer substantially reduced following infection of various mammalian cell types. Exemplar reassortant viruses also replicated to similar titers in mice, although mice infected with viruses with the avian virus-derived segment 8s had reduced weight loss compared to that achieved in mice infected with the A/Puerto Rico/8/1934 (H1N1) parent. In vitro, the viruses coped similarly with type I interferons. Temporal proteomics analysis of cellular responses to infection showed that the avian virus-derived NS segments provoked lower levels of expression of interferon-stimulated genes in cells than wild type-derived NS segments. Thus, neither the A nor the B allele of avian virus-derived NS segments necessarily attenuates virus replication in a mammalian host, although the alleles can attenuate disease. Phylogenetic analyses identified 32 independent incursions of an avian virus-derived A allele into mammals, whereas 6 introductions of a B allele were identified. However, A-allele isolates from birds outnumbered B-allele isolates, and the relative rates of Aves-to-Mammalia transmission were not significantly different. We conclude that while the introduction of an avian virus segment 8 into mammals is a relatively rare event, the dogma of the B allele being especially restricted is misleading, with implications in the assessment of the pandemic potential of avian influenza viruses. IMPORTANCE: Influenza A virus (IAV) can adapt to poultry and mammalian species, inflicting a great socioeconomic burden on farming and health care sectors. Host adaptation likely involves multiple viral factors. Here, we investigated the role of IAV segment 8. Segment 8 has evolved into two distinct clades: the A and B alleles. The B-allele genes have previously been suggested to be restricted to avian virus species. We introduced a selection of avian virus A- and B-allele segment 8s into human H1N1 and H3N2 virus backgrounds and found that these reassortant viruses were fully competent in mammalian host systems. We also analyzed the currently available public data on the segment 8 gene distribution and found surprisingly little evidence for specific avian host restriction of the B-clade segment. We conclude that B-allele segment 8 genes are, in fact, capable of supporting infection in mammals and that they should be considered during the assessment of the pandemic risk of zoonotic influenza A viruses.

Published
2016

6. Role of the B allele of the influenza A virus segment 8 in setting mammalian host range and pathogenicity

Author

Turnbull, Matthew L., Wise, Helen M., Nicol, Marlynne Q., Smith, Nikki, Dunfee, Rebecca L., Beard, Philippa M., Jagger, Brett W., Ligertwood, Yvonne, Hardisty, Gareth R., Xiao, Haixiang, Benton, Donald J., Coburn, Alice M., Paulo, Joao A., Gygi, Steven P., McCauley, John W., Taubenberger, Jeffery K., Lycett, Samantha J., Weekes, Michael P., Dutia, Bernadette M., and Digard, Paul

Subjects
viruses
Abstract

Two ‘alleles’ of segment 8 (NS) circulate in non-chiropteran influenza A viruses. The A-allele is found in avian and mammalian viruses, but the B-allele is viewed as almost exclusively avian. This might reflect that one or both of its encoded proteins (NS1 and NEP) are maladapted for replication in mammalian hosts. To test this, a number of clade A and B avian NS segments were introduced into human H1N1 and H3N2 viruses. In no case was peak virus titre substantially reduced following infection of various mammalian cell types. Exemplar reassortant viruses also replicated to similar titres in mice, although the avian segment 8s reduced weight-loss compared to the PR8 parent. In vitro, the viruses coped similarly with type I interferons. Temporal proteomics analysis of cellular responses to infection showed that the avian NS segments provoked lower expression of IFN-stimulated genes in cells than the WT. Thus, neither A- nor B-alleles of avian virus-derived NS segments necessarily attenuate virus replication in a mammalian host although they can attenuate disease. Phylogenetic analyses identified 32 independent incursions of an avian-derived A-allele into mammals compared to 6 introductions of a B-allele. However, A-allele isolates from birds outnumber B-allele samples and the relative rates of Aves to Mammalia transmission are not significantly different. We conclude that while the introduction of an avian virus segment 8 into mammals is a relatively rare event, the dogma of the B-allele being especially restricted is misleading – with implications in the assessment of pandemic potential of avian influenza viruses.

Published
2016

7. Role of the B Allele of Influenza A Virus Segment 8 in Setting Mammalian Host Range and Pathogenicity

Author

Turnbull, Matthew L., primary, Wise, Helen M., additional, Nicol, Marlynne Q., additional, Smith, Nikki, additional, Dunfee, Rebecca L., additional, Beard, Philippa M., additional, Jagger, Brett W., additional, Ligertwood, Yvonne, additional, Hardisty, Gareth R., additional, Xiao, Haixia, additional, Benton, Donald J., additional, Coburn, Alice M., additional, Paulo, Joao A., additional, Gygi, Steven P., additional, McCauley, John W., additional, Taubenberger, Jeffery K., additional, Lycett, Samantha J., additional, Weekes, Michael P., additional, Dutia, Bernadette M., additional, and Digard, Paul, additional

Published
2016
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9. Genetic Evidence for Erythrocyte Receptor Glycophorin B Expression Levels Defining a Dominant Plasmodium falciparum Invasion Pathway into Human Erythrocytes

Author

Dankwa, Selasi, Chaand, Mudit, Kanjee, Usheer, Jiang, Rays HY, Nobre, Luis V, Goldberg, Jonathan M, Bei, Amy K, Moechtar, Mischka A, Grüring, Christof, Ahouidi, Ambroise D, Ndiaye, Daouda, Dieye, Tandakha N, Mboup, Souleymane, Weekes, Michael P, and Duraisingh, Manoj T

Subjects
cultured erythrocyte, Proteomics, Erythrocytes, Plasmodium falciparum, malaria, transcriptional variation, Computational Biology, Receptors, Cell Surface, Ligands, 3. Good health, glycophorin, parasitic diseases, Humans, Glycophorins, host cell invasion, red blood cells, Protein Binding
Abstract

Plasmodium falciparum, the parasite that causes the deadliest form of malaria, has evolved multiple proteins known as invasion ligands that bind to specific erythrocyte receptors to facilitate invasion of human erythrocytes. The EBA-175/glycophorin A (GPA) and Rh5/basigin ligand-receptor interactions, referred to as invasion pathways, have been the subject of intense study. In this study, we focused on the less-characterized sialic acid-containing receptors glycophorin B (GPB) and glycophorin C (GPC). Through bioinformatic analysis, we identified extensive variation in glycophorin B (GYPB) transcript levels in individuals from Benin, suggesting selection from malaria pressure. To elucidate the importance of the GPB and GPC receptors relative to the well-described EBA-175/GPA invasion pathway, we used an ex vivo erythrocyte culture system to decrease expression of GPA, GPB, or GPC via lentiviral short hairpin RNA transduction of erythroid progenitor cells, with global surface proteomic profiling. We assessed the efficiency of parasite invasion into knockdown cells using a panel of wild-type P. falciparum laboratory strains and invasion ligand knockout lines, as well as P. falciparum Senegalese clinical isolates and a short-term-culture-adapted strain. For this, we optimized an invasion assay suitable for use with small numbers of erythrocytes. We found that all laboratory strains and the majority of field strains tested were dependent on GPB expression level for invasion. The collective data suggest that the GPA and GPB receptors are of greater importance than the GPC receptor, supporting a hierarchy of erythrocyte receptor usage in P. falciparum.

10. Role of the B Allele of Influenza A Virus Segment 8 in Setting Mammalian Host Range and Pathogenicity

Author

Turnbull, Matthew L, Wise, Helen M, Nicol, Marlynne Q, Smith, Nikki, Dunfee, Rebecca L, Beard, Philippa M, Jagger, Brett W, Ligertwood, Yvonne, Hardisty, Gareth R, Xiao, Haixia, Benton, Donald J, Coburn, Alice M, Paulo, Joao A, Gygi, Steven P, McCauley, John W, Taubenberger, Jeffery K, Lycett, Samantha J, Weekes, Michael P, Dutia, Bernadette M, and Digard, Paul

Subjects
viruses, Virus Replication, Host Specificity, Cell Line, Madin Darby Canine Kidney Cells, Birds, Mice, Viral Proteins, Dogs, Influenza A Virus, H1N1 Subtype, Orthomyxoviridae Infections, Cell Line, Tumor, Influenza, Human, Animals, Humans, Alleles, Phylogeny, Mammals, Mice, Inbred BALB C, Virulence, Influenza A Virus, H3N2 Subtype, 3. Good health, HEK293 Cells, A549 Cells, Influenza in Birds, Reassortant Viruses
Abstract

UNLABELLED: Two alleles of segment 8 (NS) circulate in nonchiropteran influenza A viruses. The A allele is found in avian and mammalian viruses, but the B allele is viewed as being almost exclusively found in avian viruses. This might reflect the fact that one or both of its encoded proteins (NS1 and NEP) are maladapted for replication in mammalian hosts. To test this, a number of clade A and B avian virus-derived NS segments were introduced into human H1N1 and H3N2 viruses. In no case was the peak virus titer substantially reduced following infection of various mammalian cell types. Exemplar reassortant viruses also replicated to similar titers in mice, although mice infected with viruses with the avian virus-derived segment 8s had reduced weight loss compared to that achieved in mice infected with the A/Puerto Rico/8/1934 (H1N1) parent. In vitro, the viruses coped similarly with type I interferons. Temporal proteomics analysis of cellular responses to infection showed that the avian virus-derived NS segments provoked lower levels of expression of interferon-stimulated genes in cells than wild type-derived NS segments. Thus, neither the A nor the B allele of avian virus-derived NS segments necessarily attenuates virus replication in a mammalian host, although the alleles can attenuate disease. Phylogenetic analyses identified 32 independent incursions of an avian virus-derived A allele into mammals, whereas 6 introductions of a B allele were identified. However, A-allele isolates from birds outnumbered B-allele isolates, and the relative rates of Aves-to-Mammalia transmission were not significantly different. We conclude that while the introduction of an avian virus segment 8 into mammals is a relatively rare event, the dogma of the B allele being especially restricted is misleading, with implications in the assessment of the pandemic potential of avian influenza viruses. IMPORTANCE: Influenza A virus (IAV) can adapt to poultry and mammalian species, inflicting a great socioeconomic burden on farming and health care sectors. Host adaptation likely involves multiple viral factors. Here, we investigated the role of IAV segment 8. Segment 8 has evolved into two distinct clades: the A and B alleles. The B-allele genes have previously been suggested to be restricted to avian virus species. We introduced a selection of avian virus A- and B-allele segment 8s into human H1N1 and H3N2 virus backgrounds and found that these reassortant viruses were fully competent in mammalian host systems. We also analyzed the currently available public data on the segment 8 gene distribution and found surprisingly little evidence for specific avian host restriction of the B-clade segment. We conclude that B-allele segment 8 genes are, in fact, capable of supporting infection in mammals and that they should be considered during the assessment of the pandemic risk of zoonotic influenza A viruses.

11. Temporal Proteomic Analysis of BK Polyomavirus Infection Reveals Virus-Induced G2 Arrest and Highly Effective Evasion of Innate Immune Sensing

Author

Caller, Laura G, Davies, Colin TR, Antrobus, Robin, Lehner, Paul J, Weekes, Michael P, and Crump, Colin M

Subjects
Proteomics, Polyomavirus Infections, Proteome, polyomavirus, Cell Cycle Proteins, Immunity, Innate, 3. Good health, Workflow, G2 Phase Cell Cycle Checkpoints, BK Virus, Host-Pathogen Interactions, Humans, cell cycle, Disease Susceptibility, innate immunity, Biomarkers, immune evasion, Disease Resistance
Abstract

BK polyomavirus (BKPyV) is a small DNA virus that establishes a life-long persistent infection in the urinary tract of most people. BKPyV is known to cause severe morbidity in renal transplant recipients and can lead to graft rejection. The simple 5.2-kbp double-stranded DNA (dsDNA) genome expresses just seven known proteins; thus, it relies heavily on the host machinery to replicate. How the host proteome changes over the course of infection is key to understanding this host-virus interplay. Here, for the first time quantitative temporal viromics has been used to quantify global changes in >9,000 host proteins in two types of primary human epithelial cells throughout 72 h of BKPyV infection. These data demonstrate the importance of cell cycle progression and pseudo-G2 arrest in effective BKPyV replication, along with a surprising lack of an innate immune response throughout the whole virus replication cycle. BKPyV thus evades pathogen recognition to prevent activation of innate immune responses in a sophisticated manner.IMPORTANCE BK polyomavirus can cause serious problems in immune-suppressed patients, in particular, kidney transplant recipients who can develop polyomavirus-associated kidney disease. In this work, we have used advanced proteomics techniques to determine the changes to protein expression caused by infection of two independent primary cell types of the human urinary tract (kidney and bladder) throughout the replication cycle of this virus. Our findings have uncovered new details of a specific form of cell cycle arrest caused by this virus, and, importantly, we have identified that this virus has a remarkable ability to evade detection by host cell defense systems. In addition, our data provide an important resource for the future study of kidney epithelial cells and their infection by urinary tract pathogens.

12. Temporal proteomic analysis of BK polyomavirus infection reveals virus-induced G2 arrest and highly effective evasion of innate immune sensing.

Author

Caller, Laura G., Davies, Colin T. R., Antrobus, Robin, Lehner, Paul J., Weekes, Michael P., and Crump, Colin M.

Subjects
*POLYOMAVIRUS diseases, *BK virus, *URINARY organs, *DNA viruses, *URINARY tract infections, *GRAFT rejection
Abstract

BK polyomavirus (BKPyV) is a small DNA virus that establishes a life-long persistent infection in the urinary tract of most people. BKPyV is known to cause severe morbidity in renal transplant recipients and can lead to graft rejection. The simple 5.2-kbp double-stranded DNA (dsDNA) genome expresses just seven known proteins; thus, it relies heavily on the host machinery to replicate. How the host proteome changes over the course of infection is key to understanding this host-virus interplay. Here, for the first time quantitative temporal viromics has been used to quantify global changes in >9,000 host proteins in two types of primary human epithelial cells throughout 72 h of BKPyV infection. These data demonstrate the importance of cell cycle progression and pseudo-G2 arrest in effective BKPyV replication, along with a surprising lack of an innate immune response throughout the whole virus replication cycle. BKPyV thus evades pathogen recognition to prevent activation of innate immune responses in a sophisticated manner. IMPORTANCE BK polyomavirus can cause serious problems in immune-suppressed patients, in particular, kidney transplant recipients who can develop polyomavirus-associated kidney disease. In this work, we have used advanced proteomics techniques to determine the changes to protein expression caused by infection of two independent primary cell types of the human urinary tract (kidney and bladder) throughout the replication cycle of this virus. Our findings have uncovered new details of a specific form of cell cycle arrest caused by this virus, and, importantly, we have identified that this virus has a remarkable ability to evade detection by host cell defense systems. In addition, our data provide an important resource for the future study of kidney epithelial cells and their infection by urinary tract pathogens. [ABSTRACT FROM AUTHOR]

Published
2019
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13. Temporal Proteomic Analysis of BK Polyomavirus Infection Reveals Virus-Induced G2 Arrest and Highly Effective Evasion of Innate Immune Sensing

Author

Colin M. Crump, Laura G Caller, Robin Antrobus, Colin Davies, Paul J. Lehner, Michael P. Weekes, Lehner, Paul J [0000-0001-9383-1054], Weekes, Michael P [0000-0003-3196-5545], Crump, Colin M [0000-0001-9918-9998], and Apollo - University of Cambridge Repository

Subjects
Proteomics, Cell cycle checkpoint, Proteome, Immunology, polyomavirus, Evasion (network security), Cell Cycle Proteins, Biology, Microbiology, Genome, Virus, Workflow, 03 medical and health sciences, Virology, medicine, Humans, Pathogen, innate immunity, 030304 developmental biology, immune evasion, Disease Resistance, 0303 health sciences, Polyomavirus Infections, Innate immune system, 030302 biochemistry & molecular biology, DNA virus, Cell cycle, Epithelium, Immunity, Innate, Virus-Cell Interactions, 3. Good health, G2 Phase Cell Cycle Checkpoints, medicine.anatomical_structure, Viral replication, Insect Science, BK Virus, Host-Pathogen Interactions, cell cycle, Disease Susceptibility, Biomarkers
Abstract

BK polyomavirus can cause serious problems in immune-suppressed patients, in particular, kidney transplant recipients who can develop polyomavirus-associated kidney disease. In this work, we have used advanced proteomics techniques to determine the changes to protein expression caused by infection of two independent primary cell types of the human urinary tract (kidney and bladder) throughout the replication cycle of this virus. Our findings have uncovered new details of a specific form of cell cycle arrest caused by this virus, and, importantly, we have identified that this virus has a remarkable ability to evade detection by host cell defense systems. In addition, our data provide an important resource for the future study of kidney epithelial cells and their infection by urinary tract pathogens., BK polyomavirus (BKPyV) is a small DNA virus that establishes a life-long persistent infection in the urinary tract of most people. BKPyV is known to cause severe morbidity in renal transplant recipients and can lead to graft rejection. The simple 5.2-kbp double-stranded DNA (dsDNA) genome expresses just seven known proteins; thus, it relies heavily on the host machinery to replicate. How the host proteome changes over the course of infection is key to understanding this host-virus interplay. Here, for the first time quantitative temporal viromics has been used to quantify global changes in >9,000 host proteins in two types of primary human epithelial cells throughout 72 h of BKPyV infection. These data demonstrate the importance of cell cycle progression and pseudo-G2 arrest in effective BKPyV replication, along with a surprising lack of an innate immune response throughout the whole virus replication cycle. BKPyV thus evades pathogen recognition to prevent activation of innate immune responses in a sophisticated manner. IMPORTANCE BK polyomavirus can cause serious problems in immune-suppressed patients, in particular, kidney transplant recipients who can develop polyomavirus-associated kidney disease. In this work, we have used advanced proteomics techniques to determine the changes to protein expression caused by infection of two independent primary cell types of the human urinary tract (kidney and bladder) throughout the replication cycle of this virus. Our findings have uncovered new details of a specific form of cell cycle arrest caused by this virus, and, importantly, we have identified that this virus has a remarkable ability to evade detection by host cell defense systems. In addition, our data provide an important resource for the future study of kidney epithelial cells and their infection by urinary tract pathogens.

Published
2019

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