Your search keyword '"Andrew E Firth"' showing total 11 results

1. The SARS-CoV-2 protein ORF3c is a mitochondrial modulator of innate immunity

Author

Hazel Stewart, Yongxu Lu, Sarah O’Keefe, Anusha Valpadashi, Luis Daniel Cruz-Zaragoza, Hendrik A. Michel, Samantha K. Nguyen, George W. Carnell, Nina Lukhovitskaya, Rachel Milligan, Irwin Jungreis, Valeria Lulla, Andrew D. Davidson, David A. Matthews, Stephen High, Peter Rehling, Edward Emmott, Jonathan L. Heeney, James R. Edgar, Geoffrey L. Smith, and Andrew E. Firth

Abstract

SUMMARYThe SARS-CoV-2 genome encodes a multitude of accessory proteins. Using comparative genomic approaches, an additional accessory protein, ORF3c, has been predicted to be encoded within the ORF3a sgmRNA. Expression of ORF3c during infection has been confirmed independently by ribosome profiling. Despite ORF3c also being present in the 2002-2003 SARS-CoV, its function has remained unexplored. Here we show that ORF3c localises to mitochondria during infection, where it inhibits innate immunity by restricting IFN-β production, but not NF-κB activation or JAK-STAT signalling downstream of type I IFN stimulation. We find that ORF3c acts after stimulation with cytoplasmic RNA helicases RIG-I or MDA5 or adaptor protein MAVS, but not after TRIF, TBK1 or phospho-IRF3 stimulation. ORF3c co-immunoprecipitates with the antiviral proteins MAVS and PGAM5 and induces MAVS cleavage by caspase-3. Together, these data provide insight into an uncharacterised mechanism of innate immune evasion by this important human pathogen.

Published

2022

2. pUL21 is a viral phosphatase adaptor that promotes herpes simplex virus replication and spread

Author

Katherine A. Brown, Guido A. Stoll, Colin M. Crump, Andrew E. Firth, Stephen C. Graham, Janet E. Deane, Susanna Colaco, Viv Connor, Yunhui Zhuang, Julia Muenzner, Yue Han, Neil A. Bryant, Cy M. Jeffries, Stanislava Svobodova, Dmitri I. Svergun, Owen S. Tutt, Tomasz H. Benedyk, Kaveesha J. Wijesinghe, Benedyk, Tomasz H [0000-0001-6420-3665], Muenzner, Julia [0000-0002-5402-5890], Wijesinghe, Kaveesha J [0000-0002-9559-9364], Zhuang, Yunhui [0000-0001-8941-3749], Colaco, Susanna [0000-0001-6307-665X], Stoll, Guido A [0000-0003-2531-9168], Tutt, Owen S [0000-0003-3045-0355], Deane, Janet E [0000-0002-4863-0330], Crump, Colin M [0000-0001-9918-9998], Graham, Stephen C [0000-0003-4547-4034], Apollo - University of Cambridge Repository, Benedyk, Tomasz [0000-0001-6420-3665], Brown, Katherine [0000-0002-8400-6922], Deane, Janet [0000-0002-4863-0330], Firth, Andrew [0000-0002-7986-9520], Crump, Colin [0000-0001-9918-9998], Graham, Stephen [0000-0003-4547-4034], Benedyk, Tomasz H. [0000-0001-6420-3665], Wijesinghe, Kaveesha J. [0000-0002-9559-9364], Stoll, Guido A. [0000-0003-2531-9168], Tutt, Owen S. [0000-0003-3045-0355], Deane, Janet E. [0000-0002-4863-0330], Crump, Colin M. [0000-0001-9918-9998], and Graham, Stephen C. [0000-0003-4547-4034]

Subjects

Cell Lines, viruses, Mutant, Herpesvirus 1, Human, Pathology and Laboratory Medicine, Virus Replication, medicine.disease_cause, Biochemistry, Chlorocebus aethiops, Medicine and Health Sciences, Post-Translational Modification, Phosphorylation, Biology (General), health care economics and organizations, Virus Release, 0303 health sciences, Kinase, Microbial Mutation, 030302 biochemistry & molecular biology, Enzymes, Precipitation Techniques, 3. Good health, Cell biology, Medical Microbiology, Viral Pathogens, Viruses, Herpes Simplex Virus-1, Biological Cultures, Pathogens, Research Article, Herpesviruses, QH301-705.5, education, Immunoblotting, Immunology, Phosphatase, Molecular Probe Techniques, Biology, Research and Analysis Methods, Microbiology, Virus, Dephosphorylation, Viral Proteins, 03 medical and health sciences, Virology, Genetics, medicine, Immunoprecipitation, Animals, Humans, ddc:610, Molecular Biology Techniques, Microbial Pathogens, Molecular Biology, Vero Cells, 030304 developmental biology, Biology and life sciences, Virus Assembly, Organisms, Phosphatases, Proteins, Correction, Herpes Simplex, Protein phosphatase 1, RC581-607, Viral Replication, Phosphoric Monoester Hydrolases, Herpes Simplex Virus, HEK293 Cells, Herpes simplex virus, Viral replication, Enzymology, Parasitology, Immunologic diseases. Allergy, DNA viruses

Abstract

The herpes simplex virus (HSV)-1 protein pUL21 is essential for efficient virus replication and dissemination. While pUL21 has been shown to promote multiple steps of virus assembly and spread, the molecular basis of its function remained unclear. Here we identify that pUL21 is a virus-encoded adaptor of protein phosphatase 1 (PP1). pUL21 directs the dephosphorylation of cellular and virus proteins, including components of the viral nuclear egress complex, and we define a conserved non-canonical linear motif in pUL21 that is essential for PP1 recruitment. In vitro evolution experiments reveal that pUL21 antagonises the activity of the virus-encoded kinase pUS3, with growth and spread of pUL21 PP1-binding mutant viruses being restored in adapted strains where pUS3 activity is disrupted. This study shows that virus-directed phosphatase activity is essential for efficient herpesvirus assembly and spread, highlighting the fine balance between kinase and phosphatase activity required for optimal virus replication., Author summary Herpes simplex virus (HSV)-1 is a highly prevalent human virus that causes life-long infections. While the most common symptom of HSV-1 infection is orofacial lesions (‘cold sores’), HSV-1 infection can also cause fatal encephalitis and it is a leading cause of infectious blindness. The HSV-1 genome encodes many proteins that dramatically remodel the environment of infected cells to promote virus replication and spread, including enzymes that add phosphate groups (kinases) to cellular and viral proteins in order to fine-tune their function. Here we identify that pUL21 is an HSV-1 protein that binds directly to protein phosphatase 1 (PP1), a highly abundant cellular enzyme that removes phosphate groups from proteins. We demonstrate that pUL21 stimulates the specific dephosphorylation of both cellular and viral proteins, including a component of the viral nuclear egress complex that is essential for efficient assembly of new HSV-1 particles. Furthermore, our in vitro evolution experiments demonstrate that pUL21 antagonises the activity of the HSV-1 kinase pUS3. Our work highlights the precise control that herpesviruses exert upon the protein environment within infected cells, and specifically the careful balance of kinase and phosphatase activity that HSV-1 requires for optimal replication and spread.

Published

2021

3. Tetherin antagonism by SARS-CoV-2 enhances virus release: multiple mechanisms including ORF3a-mediated defective retrograde traffic

Author

Hazel Stewart, Roberta Palmulli, Kristoffer H. Johansen, Naomi McGovern, Ola M. Shehata, George W. Carnell, Hannah K. Jackson, Jin S. Lee, Jonathan C. Brown, Thomas Burgoyne, Jonathan L. Heeney, Klaus Okkenhaug, Andrew E. Firth, Andrew A. Peden, and James R. Edgar

Subjects

biology, viruses, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), fungi, Golgi apparatus, biology.organism_classification, Article, respiratory tract diseases, Cell biology, body regions, symbols.namesake, Viral envelope, Downregulation and upregulation, symbols, Tetherin, Coronaviridae, Fragmentation (cell biology), skin and connective tissue diseases, Viral load

Abstract

The antiviral restriction factor, tetherin, blocks the release of several different families of enveloped viruses, including theCoronaviridae. Tetherin is an interferon-induced protein that forms parallel homodimers between the host cell and viral particles, linking viruses to the surface of infected cells and inhibiting their release. We demonstrated that SARS-CoV-2 infection causes tetherin downregulation, and that tetherin depletion from cells enhances SARS-CoV-2 viral titres. We investigated the potential viral proteins involved in abrogating tetherin function and found that SARS- CoV-2 ORF3a reduces tetherin localisation within biosynthetic organelles via reduced retrograde recycling and increases tetherin localisation to late endocytic organelles. By removing tetherin from the Coronavirus budding compartments, ORF3a enhances virus release. We also found expression of Spike protein caused a reduction in cellular tetherin levels. Our results confirm that tetherin acts as a host restriction factor for SARS-CoV-2 and highlight the multiple distinct mechanisms by which SARS-CoV-2 subverts tetherin function.Author SummarySince it was identified in 2019, SARS-CoV-2 has displayed voracious transmissibility which has resulted in rapid spread of the virus and a global pandemic. SARS-CoV-2 is a member of theCoronaviridaefamily whose members are encapsulated by a host-derived protective membrane shell. Whilst the viral envelope may provide protection for the virus, it also provides an opportunity for the host cell to restrict the virus and stop it spreading. The anti-viral restriction factor, tetherin, acts to crosslink viruses to the surface of infected cells and prevent their spread to uninfected cells. Here, we demonstrate that SARS-CoV-2 undergoes viral restriction by tetherin, and that SARS-CoV-2 moves tetherin away from the site of Coronavirus budding to enhance its ability to escape and infect naïve cells. Tetherin depletion from cells enhanced SARS-CoV-2 viral release and increased propagation of the virus. We found that the SARS-CoV-2 protein, ORF3a, redirects tetherin away from the biosynthetic organelles where tetherin would become incorporated to newly forming SARS-CoV-2 virions – and instead relocalises tetherin to late endocytic organelles. We also found that SARS-CoV-2 Spike downregulates tetherin. These two mechanisms, in addition to the well described antagonism of interferon and subsequent ISGs highlight the multiple mechanisms by which SARS-CoV-2 abrogates tetherin function. Our study provides new insights into how SARS-CoV-2 subverts human antiviral responses and escapes from infected cells.

Published

2021

4. The stem loop 2 motif is a site of vulnerability for SARS-CoV-2

Author

Kotryna Bloznelyte, Valeria Lulla, Xiaofei Yang, Sara M. O'Rourke, Ben F. Luisi, William G. Scott, Mary Wu, Felix Randow, Yiliang Ding, Rachel Ulferts, Nicole Doyle, Michal P. Wandel, Stephanie Oerum, Rupert Beale, Helena J. Maier, Tom Dendooven, Andrew E. Firth, and Katarzyna J Bandyra

Subjects

Untranslated region, viruses, virus diseases, RNA, Replicon, RNA Cleavage, Biology, biology.organism_classification, Stem-loop, Virology, Astrovirus, Conserved sequence, Subgenomic mRNA

Abstract

SummaryRNA structural elements occur in numerous single stranded (+)-sense RNA viruses. The stemloop 2 motif (s2m) is one such element with an unusually high degree of sequence conservation, being found in the 3’ UTR in the genomes of many astroviruses, some picornaviruses and noroviruses, and a variety of coronaviruses, including SARS-CoV and SARS-CoV-2. The evolutionary conservation and its occurrence in all viral subgenomic transcripts implicates a key role of s2m in the viral infection cycle. Our findings indicate that the element, while stably folded, can nonetheless be invaded and remodelled spontaneously by antisense oligonucleotides (ASOs) that initiate pairing in exposed loops and trigger efficient sequence-specific RNA cleavage in reporter assays. ASOs also act to inhibit replication in an astrovirus replicon model system in a sequence-specific, dose-dependent manner and inhibit SARS-CoV-2 infection in cell culture. Our results thus permit us to suggest that the s2m element is a site of vulnerability readily targeted by ASOs, which show promise as anti-viral agents.

Published

2020

5. Structural and molecular basis for Cardiovirus 2A protein as a viral gene expression switch

Author

Sawsan Napthine, Neva Caliskan, Lukas Pekarek, Stephen C. Graham, Chris H. Hill, Ian Brierley, Andrew E. Firth, and Anuja Kibe

Subjects

Elongation factor, Mutation, Translational frameshift, Chemistry, Gene expression, medicine, RNA, Translation (biology), medicine.disease_cause, Genome, Ribosome, Cell biology

Abstract

Programmed −1 ribosomal frameshifting (PRF) in cardioviruses is activated by the 2A protein: a multi-functional virulence factor that also inhibits cap-dependent translational initiation. Here we present the X-ray crystal structure of 2A and show that it selectively binds to and stabilises the PRF stimulatory RNA element in the viral genome. Using optical tweezers, we define the conformational repertoire of this element and measure changes in unfolding pathways arising from mutation and 2A binding. Next, we demonstrate a strong interaction between 2A and the small ribosomal subunit and present a cryo-EM structure of 2A bound to initiated 70S ribosomes. Multiple copies of 2A bind to the 16S rRNA where they may compete for binding with initiation and elongation factors. Together, these results define the structural basis for RNA recognition by 2A, expand our understanding of the 2A-dependent gene expression switch and reveal how 2A accumulation may shut down translation during virus infection.

Published

2020

6. A putative new SARS-CoV protein, 3a*, encoded in an ORF overlapping ORF3a

Author

Andrew E. Firth

Subjects

chemistry.chemical_classification, 0303 health sciences, 030302 biochemistry & molecular biology, Translation (biology), Computational biology, Biology, Transmembrane protein, Amino acid, 03 medical and health sciences, Open reading frame, chemistry, Identification (biology), Ribosome profiling, Subgenus, Gene, 030304 developmental biology

Abstract

Identification of the full complement of genes in SARS-CoV-2 is a crucial step towards gaining a fuller understanding of its molecular biology. However, short and/or overlapping genes can be difficult to detect using conventional computational approaches, whereas high throughput experimental approaches – such as ribosome profiling – cannot distinguish translation of functional peptides from regulatory translation or translational noise. By studying regions showing enhanced conservation at synonymous sites in alignments of SARS-CoV and related viruses (subgenus Sarbecovirus), and correlating with the conserved presence of an open reading frame and plausible translation mechanism, we identified a putative new gene, ORF3a*, overlapping ORF3a in an alternative reading frame. A recently published ribosome profiling study confirmed that ORF3a* is indeed translated during infection. ORF3a* is conserved across the subgenus Sarbecovirus, and encodes a 40–41 amino acid predicted transmembrane protein.

Published

2020

7. Upstream translation initiation expands the coding capacity of segmented negative-strand RNA viruses

Author

Ian Brierley, Maria João Amorim, Ingeborg van Knippenberg, Helen M. Wise, J Kenneth Baillie, Liliane Chung, Robert J. Gifford, Quan Gu, Bo Wang, Sara Clohisey, Edward C. Hutchinson, Paul Digard, Adam M. Dinan, Veronica V. Rezelj, Joshua D. Jones, Nerea Irigoyen, Andrew E. Firth, Elizabeth Sloan, Marta Alenquer, and Megan K. L. MacLeod

Subjects

Genetics, 0303 health sciences, 030306 microbiology, viruses, RNA, Translation (biology), Biology, Genome, 03 medical and health sciences, Open reading frame, Eukaryotic translation, Gene expression, ORFS, Gene, 030304 developmental biology

Abstract

Segmented negative-strand RNA viruses (sNSVs) include the influenza viruses, the bunyaviruses, and other major pathogens of humans, other animals and plants. The genomes of these viruses are extremely short. In response to this severe genetic constraint, sNSVs use a variety of strategies to maximise their coding potential. Because the eukaryotic hosts parasitized by sNSVs can regulate gene expression through low levels of translation initiation upstream of their canonical open reading frames (ORFs), we asked whether sNSVs could use upstream translation initiation to expand their own genetic repertoires. Consistent with this hypothesis, we showed that influenza A viruses (IAVs) and bunyaviruses were capable of upstream translation initiation. Using a combination of reporter assays and viral infections, we found that upstream translation in IAVs can initiate in two unusual ways: through non-AUG initiation in virally encoded ‘untranslated’ regions, and through the appropriation of an AUG-containing leader sequence from host mRNAs through viral cap-snatching, a process we termed ‘start-snatching.’ Finally, while upstream translation of cellular genes is mainly regulatory, for sNSVs it also has the potential to create novel viral gene products. If in frame with a viral ORF, this creates N-extensions of canonical viral proteins. If not, it allows the expression of cryptic overlapping ORFs, which we found were highly conserved in IAV and widely distributed in peribunyaviruses. Thus, by exploiting their host’s capacity for upstream translation initiation, sNSVs can expand still further the coding potential of their extremely compact RNA genomes.

Published

2019

8. A case for a reverse-frame coding sequence in a group of positive-sense RNA viruses

Author

Adam M. Dinan, Ingrida Olendraite, Nina I. Lukhovitskaya, and Andrew E. Firth

Subjects

Genetics, 0303 health sciences, biology, 030302 biochemistry & molecular biology, RNA, RNA virus, biology.organism_classification, Stop codon, 03 medical and health sciences, chemistry.chemical_compound, Open reading frame, chemistry, RNA polymerase, Coding region, ORFS, Gene, 030304 developmental biology

Abstract

Positive-sense single-stranded RNA viruses form the largest and most diverse group of eukaryote-infecting viruses. Their genomes comprise one or more segments of coding-sense RNA that function directly as messenger RNAs upon release into the cytoplasm of infected cells. Positive-sense RNA viruses are generally accepted to encode proteins solely on the positive strand. However, we previously identified a surprisingly long (~1000 codons) open reading frame (ORF) on the negative strand of some members of the familyNarnaviridaewhich, together with RNA bacteriophages of the familyLeviviridae, form a sister group to all other positive-sense RNA viruses. Here, we completed the genomes of three mosquito-associated narnaviruses, all of which have the long reverse-frame ORF. We systematically identified narnaviral sequences in public data sets from a wide range of sources, including arthropod, fungi and plant transcriptomic datasets. Long reverse-frame ORFs are widespread in one clade of narnaviruses, where they frequently occupy >95% of the genome. The reverse-frame ORFs correspond to a specific avoidance of CUA, UUA and UCA codons (i.e. stop codon reverse complements) in the forward-frame RNA-dependent RNA polymerase ORF. However, absence of these codons cannot be explained by other factors such as inability to decode these codons or GC3 bias. Together with other analyses, we provide the strongest evidence yet of coding capacity on the negative strand of a positive-sense RNA virus. As these ORFs comprise some of the longest known overlapping genes, their study may be of broad relevance to understanding overlapping gene evolution andde novoorigin of genes.

Published

2019

9. A hidden gene in astroviruses encodes a cell-permeabilizing protein involved in virus release

Author

Andrew E. Firth and Valeria Lulla

Subjects

0303 health sciences, biology, 030306 microbiology, viruses, RNA, virus diseases, biology.organism_classification, Virology, Virus, 3. Good health, Astrovirus, 03 medical and health sciences, Open reading frame, fluids and secretions, Viral envelope, Replicon, Ribosome profiling, Gene, 030304 developmental biology

Abstract

Human astroviruses are small nonenveloped viruses with positive-sense single-stranded RNA genomes that contain three main open reading frames: ORF1a, ORF1b and ORF2. Astroviruses cause acute gastroenteritis in children worldwide and have been associated with encephalitis and meningitis in immunocompromised individuals. Through comparative genomic analysis of >400 astrovirus sequences, we identified a conserved “ORFX” overlapping the capsid-encoding ORF2 in genogroup I, III and IV astroviruses. ORFX appears to be subject to purifying selection, consistent with it encoding a functional protein product, termed XP. Using ribosome profiling of cells infected with human astrovirus 1, we confirm initiation at the ORFX AUG. XP-knockout astroviruses are strongly attenuated and after passaging can partly restore viral titer via pseudo-reversions, thus demonstrating that XP plays an important role in virus growth. To further investigate XP, we developed an astrovirus replicon system. We demonstrate that XP has only minor effects on RNA replication and structural protein production. Instead, XP associates with the plasma membrane with an extracellular N-terminus topology and promotes efficient virus release. Using two different assays, we show that expression of human or related astrovirus XPs leads to cell permeabilization, suggesting a viroporin-like activity. The discovery of XP advances our knowledge of these important human viruses and opens a new direction of research into astrovirus replication and pathogenesis.

Published

2019

10. The transcriptional and translational landscape of equine torovirus

Author

Hazel Stewart, Eric J. Snijder, Nerea Irigoyen, Adam M. Dinan, Katherine A. Brown, and Andrew E. Firth

Subjects

Genetics, biology, Transcription (biology), Torovirus, RNA, Ribosome profiling, ORFS, Torovirinae, biology.organism_classification, Ribosome, Subgenomic mRNA

Abstract

The genusTorovirus(subfamilyTorovirinae, familyCoronaviridae, orderNidovirales) encompasses a range of species that infect domestic ungulates including cattle, sheep, goats, pigs and horses, causing an acute self-limiting gastroenteritis. Using the prototype species equine torovirus (EToV) we performed parallel RNA sequencing (RNA-seq) and ribosome profiling (Ribo-seq) to analyse the relative expression levels of the known torovirus proteins and transcripts, chimaeric sequences produced via discontinuous RNA synthesis (a characteristic of the nidovirus replication cycle) and changes in host transcription and translation as a result of EToV infection. RNA sequencing confirmed that EToV utilises a unique combination of discontinuous and non-discontinuous RNA synthesis to produce its subgenomic RNAs; indeed, we identified transcripts arising from both mechanisms that would result in sgRNAs encoding the nucleocapsid. Our ribosome profiling analysis revealed that ribosomes efficiently translate two novel CUG-initiated ORFs, located within the so-called 5’ UTR. We have termed the resulting proteins U1 and U2. Comparative genomic analysis confirmed that these ORFs are conserved across all available torovirus sequences and the inferred amino acid sequences are subject to purifying selection, indicating that U1 and U2 are functionally relevant. This study provides the first high-resolution analysis of transcription and translation in this neglected group of livestock pathogens.ImportanceToroviruses infect cattle, goats, pigs and horses worldwide and can cause gastrointestinal disease. There is no treatment or vaccine and their ability to spill over into humans has not been assessed. These viruses are related to important human pathogens including severe acute respiratory syndrome (SARS) coronavirus and they share some common features, however the mechanism that they use to produce subgenomic RNA molecules differs. Here we performed deep sequencing to determine how equine torovirus produces subgenomic RNAs. In doing so, we also identified two previously unknown open reading frames “hidden” within the genome. Together these results highlight the similarities and differences between this domestic animal virus and related pathogens of humans and livestock.

Published

2018

11. Observation of dually decoded regions of the human genome using ribosome profiling data

Author

Pavel V. Baranov, John F. Atkins, Nicholas T. Ingolia, Audrey M. Michel, Andrew E. Firth, and Kingshuk Roy Choudhury

Subjects

Genetics, Translational frameshift, Binding Sites, DNA, Complementary, Genome, Human, Reading frame, Method, Translation (biology), Sequence Analysis, DNA, Biology, Ribosome, Open Reading Frames, Open reading frame, Protein Biosynthesis, Humans, Coding region, Human genome, RNA, Messenger, Ribosome profiling, Ribosomes, Genetics (clinical)

Abstract

The recently developed ribosome profiling technique (Ribo-Seq) allows mapping of the locations of translating ribosomes on mRNAs with subcodon precision. When ribosome protected fragments (RPFs) are aligned to mRNA, a characteristic triplet periodicity pattern is revealed. We utilized the triplet periodicity of RPFs to develop a computational method for detecting transitions between reading frames that occur during programmed ribosomal frameshifting or in dual coding regions where the same nucleotide sequence codes for multiple proteins in different reading frames. Application of this method to ribosome profiling data obtained for human cells allowed us to detect several human genes where the same genomic segment is translated in more than one reading frame (from different transcripts as well as from the same mRNA) and revealed the translation of hitherto unpredicted coding open reading frames.

Published

2012