Your search keyword '"Harrison, Stephen C."' showing total 23 results

1. The rotavirus VP5*/VP8* conformational transition permeabilizes membranes to Ca2.

Author

de Sautu M, Herrmann T, Scanavachi G, Jenni S, and Harrison SC

Subjects

Capsid Proteins metabolism, Capsid metabolism, Calcium metabolism, Liposomes analysis, Liposomes metabolism, Rotavirus genetics

Abstract

Rotaviruses infect cells by delivering into the cytosol a transcriptionally active inner capsid particle (a "double-layer particle": DLP). Delivery is the function of a third, outer layer, which drives uptake from the cell surface into small vesicles from which the DLPs escape. In published work, we followed stages of rhesus rotavirus (RRV) entry by live-cell imaging and correlated them with structures from cryogenic electron microscopy and tomography (cryo-EM and cryo-ET). The virus appears to wrap itself in membrane, leading to complete engulfment and loss of Ca2+ from the vesicle produced by the wrapping. One of the outer-layer proteins, VP7, is a Ca2+-stabilized trimer; loss of Ca2+ releases both VP7 and the other outer-layer protein, VP4, from the particle. VP4, activated by cleavage into VP8* and VP5*, is a trimer that undergoes a large-scale conformational rearrangement, reminiscent of the transition that viral fusion proteins undergo to penetrate a membrane. The rearrangement of VP5* thrusts a 250-residue, C-terminal segment of each of the three subunits outward, while allowing the protein to remain attached to the virus particle and to the cell being infected. We proposed that this segment inserts into the membrane of the target cell, enabling Ca2+ to cross. In the work reported here, we show the validity of key aspects of this proposed sequence. By cryo-EM studies of liposome-attached virions ("triple-layer particles": TLPs) and single-particle fluorescence imaging of liposome-attached TLPs, we confirm insertion of the VP4 C-terminal segment into the membrane and ensuing generation of a Ca2+ "leak". The results allow us to formulate a molecular description of early events in entry. We also discuss our observations in the context of other work on double-strand RNA virus entry., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 de Sautu et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

2. Rotavirus VP4 Epitope of a Broadly Neutralizing Human Antibody Defined by Its Structure Bound with an Attenuated-Strain Virion.

Author

Jenni S, Li Z, Wang Y, Bessey T, Salgado EN, Schmidt AG, Greenberg HB, Jiang B, and Harrison SC

Subjects

Animals, Cryoelectron Microscopy, Humans, Immunoglobulin Fab Fragments immunology, Immunoglobulin Fab Fragments ultrastructure, Mice, Protein Conformation, Rats, Serial Passage, Broadly Neutralizing Antibodies immunology, Broadly Neutralizing Antibodies ultrastructure, Capsid Proteins chemistry, Capsid Proteins immunology, Capsid Proteins ultrastructure, Epitopes, B-Lymphocyte immunology, Epitopes, B-Lymphocyte ultrastructure, Rotavirus chemistry, Rotavirus classification, Rotavirus immunology, Rotavirus physiology, Vaccines, Attenuated chemistry, Vaccines, Attenuated immunology, Vaccines, Attenuated metabolism, Virion immunology, Virion metabolism, Virion ultrastructure

Abstract

Rotavirus live-attenuated vaccines, both mono- and pentavalent, generate broadly heterotypic protection. B-cells isolated from adults encode neutralizing antibodies, some with affinity for VP5*, that afford broad protection in mice. We have mapped the epitope of one such antibody by determining the high-resolution cryo-EM structure of its antigen-binding fragment (Fab) bound to the virion of a candidate vaccine strain, CDC-9. The Fab contacts both the distal end of a VP5* β-barrel domain and the two VP8* lectin-like domains at the tip of a projecting spike. Its interactions with VP8* do not impinge on the likely receptor-binding site, suggesting that the mechanism of neutralization is at a step subsequent to initial attachment. We also examined structures of CDC-9 virions from two different stages of serial passaging. Nearly all the VP4 (cleaved to VP8*/VP5*) spikes on particles from the earlier passage (wild-type isolate) had transitioned from the "upright" conformation present on fully infectious virions to the "reversed" conformation that is probably the end state of membrane insertion, unable to mediate penetration, consistent with the very low in vitro infectivity of the wild-type isolate. About half the VP4 spikes were upright on particles from the later passage, which had recovered substantial in vitro infectivity but had acquired an attenuated phenotype in neonatal rats. A mutation in VP4 that occurred during passaging appears to stabilize the interface at the apex of the spike and could account for the greater stability of the upright spikes on the late-passage, attenuated isolate. IMPORTANCE Rotavirus live-attenuated vaccines generate broadly heterotypic protection, and B-cells isolated from adults encode antibodies that are broadly protective in mice. Determining the structural and mechanistic basis of broad protection can contribute to understanding the current limitations of vaccine efficacy in developing countries. The structure of an attenuated human rotavirus isolate (CDC-9) bound with the Fab fragment of a broadly heterotypic protective antibody shows that protection is probably due to inhibition of the conformational transition in the viral spike protein (VP4) critical for viral penetration, rather than to inhibition of receptor binding. A comparison of structures of CDC-9 virus particles at two stages of serial passaging supports a proposed mechanism for initial steps in rotavirus membrane penetration.

Published

2022

3. Functional refolding of the penetration protein on a non-enveloped virus.

Author

Herrmann T, Torres R, Salgado EN, Berciu C, Stoddard D, Nicastro D, Jenni S, and Harrison SC

Subjects

Animals, Antigens, Viral metabolism, Capsid Proteins genetics, Capsid Proteins metabolism, Cell Line, Cell Membrane chemistry, Cell Membrane metabolism, Cell Membrane ultrastructure, Disulfides chemistry, Disulfides metabolism, Models, Molecular, Mutant Proteins chemistry, Mutant Proteins genetics, Mutant Proteins metabolism, Mutant Proteins ultrastructure, Mutation, Protein Conformation, RNA-Binding Proteins metabolism, Rotavirus chemistry, Rotavirus physiology, Viral Nonstructural Proteins metabolism, Virion chemistry, Virion metabolism, Virion ultrastructure, Capsid Proteins chemistry, Capsid Proteins ultrastructure, Cryoelectron Microscopy, Protein Refolding, Rotavirus metabolism, Rotavirus ultrastructure, Virus Internalization

Abstract

A non-enveloped virus requires a membrane lesion to deliver its genome into a target cell 1 . For rotaviruses, membrane perforation is a principal function of the viral outer-layer protein, VP4 2,3 . Here we describe the use of electron cryomicroscopy to determine how VP4 performs this function and show that when activated by cleavage to VP8* and VP5*, VP4 can rearrange on the virion surface from an 'upright' to a 'reversed' conformation. The reversed structure projects a previously buried 'foot' domain outwards into the membrane of the host cell to which the virion has attached. Electron cryotomograms of virus particles entering cells are consistent with this picture. Using a disulfide mutant of VP4, we have also stabilized a probable intermediate in the transition between the two conformations. Our results define molecular mechanisms for the first steps of the penetration of rotaviruses into the membranes of target cells and suggest similarities with mechanisms postulated for other viruses.

Published

2021

4. In situ Structure of Rotavirus VP1 RNA-Dependent RNA Polymerase.

Author

Jenni S, Salgado EN, Herrmann T, Li Z, Grant T, Grigorieff N, Trapani S, Estrozi LF, and Harrison SC

Subjects

Binding Sites, Capsid Proteins chemistry, Models, Molecular, Protein Conformation, Protein Interaction Domains and Motifs, RNA, Double-Stranded, Rotavirus genetics, Transcription, Genetic, Viral Core Proteins, Virus Replication, RNA-Dependent RNA Polymerase chemistry, RNA-Dependent RNA Polymerase metabolism, Rotavirus metabolism

Abstract

Rotaviruses, like other non-enveloped, double-strand RNA viruses, package an RNA-dependent RNA polymerase (RdRp) with each duplex of their segmented genomes. Rotavirus cell entry results in loss of an outer protein layer and delivery into the cytosol of an intact, inner capsid particle (the "double-layer particle," or DLP). The RdRp, designated VP1, is active inside the DLP; each VP1 achieves many rounds of mRNA transcription from its associated genome segment. Previous work has shown that one VP1 molecule lies close to each 5-fold axis of the icosahedrally symmetric DLP, just beneath the inner surface of its protein shell, embedded in tightly packed RNA. We have determined a high-resolution structure for the rotavirus VP1 RdRp in situ, by local reconstruction of density around individual 5-fold positions. We have analyzed intact virions ("triple-layer particles"), non-transcribing DLPs and transcribing DLPs. Outer layer dissociation enables the DLP to synthesize RNA, in vitro as well as in vivo, but appears not to induce any detectable structural change in the RdRp. Addition of NTPs, Mg 2+ , and S-adenosylmethionine, which allows active transcription, results in conformational rearrangements, in both VP1 and the DLP capsid shell protein, that allow a transcript to exit the polymerase and the particle. The position of VP1 (among the five symmetrically related alternatives) at one vertex does not correlate with its position at other vertices. This stochastic distribution of site occupancies limits long-range order in the 11-segment, double-strand RNA genome., (Copyright © 2019 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2019

5. Visualization of Calcium Ion Loss from Rotavirus during Cell Entry.

Author

Salgado EN, Garcia Rodriguez B, Narayanaswamy N, Krishnan Y, and Harrison SC

Subjects

Animals, Antigens, Viral chemistry, Antigens, Viral metabolism, Capsid chemistry, Capsid metabolism, Capsid Proteins chemistry, Cell Line, Cytosol virology, Microscopy, Confocal, Protein Conformation, Virus Internalization, Calcium metabolism, Capsid Proteins metabolism, Fluorescent Dyes chemistry, Rotavirus physiology

Abstract

Bound calcium ions stabilize many nonenveloped virions. Loss of Ca 2+ from these particles appears to be a regulated part of entry or uncoating. The outer layer of an infectious rotavirus triple-layered particle (TLP) comprises a membrane-interacting protein (VP4) anchored by a Ca 2+ -stabilized protein (VP7). Membrane-coupled conformational changes in VP4 (cleaved to VP8* and VP5*) and dissociation of VP4 and VP7 accompany penetration of the double-layered inner capsid particle (DLP) into the cytosol. Removal of Ca 2+ in vitro strips away both outer layer proteins; we and others have postulated that the loss of Ca 2+ triggers molecular events in viral penetration. We have now investigated, with the aid of a fluorescent Ca 2+ sensor, the timing of Ca 2+ loss from entering virions with respect to the dissociation of VP4 and VP7. In live-cell imaging experiments, distinct fluorescent markers on the DLP and on VP7 report on outer layer dissociation and DLP release. The Ca 2+ sensor, placed on VP5*, monitors the Ca 2+ concentration within the membrane-bound vesicle enclosing the entering particle. Slow (1-min duration) loss of Ca 2+ precedes the onset of VP7 dissociation by about 2 min and DLP release by about 7 min. Coupled with our previous results showing that VP7 loss follows tight binding to the cell surface by about 5 min, these data indicate that Ca 2+ Nonenveloped viruses penetrate into the cytosol of the cells that they infect by disrupting the membrane of an intracellular compartment. The molecular mechanisms of membrane disruption remain largely undefined. Functional reconstitution of infectious rotavirus particles (TLPs) from RNA-containing core particles (DLPs) and the outer layer proteins that deliver them into a cell makes these important pediatric pathogens particularly good models for studying nonenveloped virus entry. We report here how the use of a fluorescent Ca IMPORTANCE Nonenveloped viruses penetrate into the cytosol of the cells that they infect by disrupting the membrane of an intracellular compartment. The molecular mechanisms of membrane disruption remain largely undefined. Functional reconstitution of infectious rotavirus particles (TLPs) from RNA-containing core particles (DLPs) and the outer layer proteins that deliver them into a cell makes these important pediatric pathogens particularly good models for studying nonenveloped virus entry. We report here how the use of a fluorescent Ca 2+ sensor, covalently linked to one of the viral proteins, allows us to establish, using live-cell imaging, the timing of Ca 2+ loss from an entering particle and other molecular events in the entry pathway. Specific Ca 2+ binding stabilizes many other viruses of eukaryotes, and Ca 2+ loss appears to be a trigger for steps in penetration or uncoating. The experimental design that we describe may be useful for studying entry of other viral pathogens., (Copyright © 2018 Salgado et al.)

Published

2018

6. Structural correlates of rotavirus cell entry.

Author

Abdelhakim AH, Salgado EN, Fu X, Pasham M, Nicastro D, Kirchhausen T, and Harrison SC

Subjects

Animals, Antigens, Viral chemistry, Antigens, Viral genetics, Capsid Proteins chemistry, Capsid Proteins genetics, Cell Membrane metabolism, Cells, Cultured, Chlorocebus aethiops virology, Image Processing, Computer-Assisted, Kidney virology, Microscopy, Electron, Mutation genetics, Rotavirus physiology, Antigens, Viral metabolism, Capsid Proteins metabolism, Cell Membrane chemistry, Rotavirus chemistry, Virion, Virus Assembly physiology, Virus Internalization

Abstract

Cell entry by non-enveloped viruses requires translocation into the cytosol of a macromolecular complex--for double-strand RNA viruses, a complete subviral particle. We have used live-cell fluorescence imaging to follow rotavirus entry and penetration into the cytosol of its ∼ 700 Å inner capsid particle ("double-layered particle", DLP). We label with distinct fluorescent tags the DLP and each of the two outer-layer proteins and track the fates of each species as the particles bind and enter BSC-1 cells. Virions attach to their glycolipid receptors in the host cell membrane and rapidly become inaccessible to externally added agents; most particles that release their DLP into the cytosol have done so by ∼ 10 minutes, as detected by rapid diffusional motion of the DLP away from residual outer-layer proteins. Electron microscopy shows images of particles at various stages of engulfment into tightly fitting membrane invaginations, consistent with the interpretation that rotavirus particles drive their own uptake. Electron cryotomography of membrane-bound virions also shows closely wrapped membrane. Combined with high resolution structural information about the viral components, these observations suggest a molecular model for membrane disruption and DLP penetration.

Published

2014

7. Location of the dsRNA-dependent polymerase, VP1, in rotavirus particles.

Author

Estrozi LF, Settembre EC, Goret G, McClain B, Zhang X, Chen JZ, Grigorieff N, and Harrison SC

Subjects

Cryoelectron Microscopy, Crystallography, X-Ray, Image Processing, Computer-Assisted, Models, Molecular, RNA, Double-Stranded genetics, RNA, Messenger genetics, RNA, Viral genetics, Rotavirus chemistry, Rotavirus genetics, Rotavirus ultrastructure, Viral Core Proteins genetics, Virus Assembly, Capsid chemistry, Rotavirus enzymology, Viral Core Proteins chemistry, Viral Core Proteins metabolism

Abstract

Double-stranded RNA (dsRNA) viruses transcribe and replicate RNA within an assembled, inner capsid particle; only plus-sense mRNA emerges into the intracellular milieu. During infectious entry of a rotavirus particle, the outer layer of its three-layer structure dissociates, delivering the inner double-layered particle (DLP) into the cytosol. DLP structures determined by X-ray crystallography and electron cryomicroscopy (cryoEM) show that the RNA coils uniformly into the particle interior, avoiding a "fivefold hub" of more structured density projecting inward from the VP2 shell of the DLP along each of the twelve 5-fold axes. Analysis of the X-ray crystallographic electron density map suggested that principal contributors to the hub are the N-terminal arms of VP2, but reexamination of the cryoEM map has shown that many features come from a molecule of VP1, randomly occupying five equivalent and partly overlapping positions. We confirm here that the electron density in the X-ray map leads to the same conclusion, and we describe the functional implications of the orientation and position of the polymerase. The exit channel for the nascent transcript directs the nascent transcript toward an opening along the 5-fold axis. The template strand enters from within the particle, and the dsRNA product of the initial replication step exits in a direction tangential to the inner surface of the VP2 shell, allowing it to coil optimally within the DLP. The polymerases of reoviruses appear to have similar positions and functional orientations., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2013

8. Movies of ice-embedded particles enhance resolution in electron cryo-microscopy.

Author

Campbell MG, Cheng A, Brilot AF, Moeller A, Lyumkis D, Veesler D, Pan J, Harrison SC, Potter CS, Carragher B, and Grigorieff N

Subjects

Cryoelectron Microscopy methods, Ice, Rotavirus ultrastructure

Abstract

Low-dose images obtained by electron cryo-microscopy (cryo-EM) are often affected by blurring caused by sample motion during electron beam exposure, degrading signal especially at high resolution. We show here that we can align frames of movies, recorded with a direct electron detector during beam exposure of rotavirus double-layered particles, thereby greatly reducing image blurring caused by beam-induced motion and sample stage instabilities. This procedure increases the efficiency of cryo-EM imaging and enhances the resolution obtained in three-dimensional reconstructions of the particle. Using movies in this way is generally applicable to all cryo-EM samples and should also improve the performance of midrange electron microscopes that may have limited mechanical stability and beam coherence., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

9. Cross-linking of rotavirus outer capsid protein VP7 by antibodies or disulfides inhibits viral entry.

Author

Aoki ST, Trask SD, Coulson BS, Greenberg HB, Dormitzer PR, and Harrison SC

Subjects

Animals, Antibodies, Neutralizing immunology, Antibodies, Viral immunology, Antigens, Viral chemistry, Antigens, Viral immunology, Capsid Proteins chemistry, Capsid Proteins immunology, Cell Line, Disulfides metabolism, Macaca mulatta, Antigens, Viral metabolism, Capsid Proteins metabolism, Rotavirus physiology, Virus Internalization

Abstract

Antibodies that neutralize rotavirus infection target outer coat proteins VP4 and VP7 and inhibit viral entry. The structure of a VP7-Fab complex (S. T. Aoki, et al., Science 324:1444-1447, 2009) led us to reclassify epitopes into two binding regions at inter- and intrasubunit boundaries of the calcium-dependent trimer. It further led us to show that antibodies binding at the intersubunit boundary inhibit uncoating of the virion outer layer. We have now tested representative antibodies for each of the defined structural epitope regions and find that antibodies recognizing epitopes in either binding region neutralize by cross-linking VP7 trimers. Antibodies that bind at the intersubunit junction neutralize as monovalent Fabs, while those that bind at the intrasubunit region require divalency. The VP7 structure has also allowed us to design a disulfide cross-linked VP7 mutant which recoats double-layered particles (DLPs) as efficiently as does wild-type VP7 but which yields particles defective in cell entry as determined both by lack of infectivity and by loss of α-sarcin toxicity in the presence of recoated particles. We conclude that dissociation of the VP7 trimer is an essential step in viral penetration into cells.

Published

2011

10. Atomic model of an infectious rotavirus particle.

Author

Settembre EC, Chen JZ, Dormitzer PR, Grigorieff N, and Harrison SC

Subjects

Cell Membrane metabolism, Cryoelectron Microscopy, Crystallography, Protein Structure, Secondary, Rotavirus metabolism, Capsid Proteins genetics, Models, Molecular, Rotavirus ultrastructure, Virion ultrastructure, Virus Internalization

Abstract

Non-enveloped viruses of different types have evolved distinct mechanisms for penetrating a cellular membrane during infection. Rotavirus penetration appears to occur by a process resembling enveloped-virus fusion: membrane distortion linked to conformational changes in a viral protein. Evidence for such a mechanism comes from crystallographic analyses of fragments of VP4, the rotavirus-penetration protein, and infectivity analyses of structure-based VP4 mutants. We describe here the structure of an infectious rotavirus particle determined by electron cryomicroscopy (cryoEM) and single-particle analysis at about 4.3 Å resolution. The cryoEM image reconstruction permits a nearly complete trace of the VP4 polypeptide chain, including the positions of most side chains. It shows how the two subfragments of VP4 (VP8(*) and VP5(*)) retain their association after proteolytic cleavage, reveals multiple structural roles for the β-barrel domain of VP5(*), and specifies interactions of VP4 with other capsid proteins. The virion model allows us to integrate structural and functional information into a coherent mechanism for rotavirus entry.

Published

2011

11. Effect of mutations in VP5 hydrophobic loops on rotavirus cell entry.

Author

Kim IS, Trask SD, Babyonyshev M, Dormitzer PR, and Harrison SC

Subjects

Animals, Cell Line, Hydrophobic and Hydrophilic Interactions, Macaca mulatta, Rotavirus chemistry, Rotavirus genetics, Viral Nonstructural Proteins metabolism, Mutation, Rotavirus physiology, Viral Nonstructural Proteins chemistry, Viral Nonstructural Proteins genetics, Virus Internalization

Abstract

Experiments in cell-free systems have demonstrated that the VP5 cleavage fragment of the rotavirus spike protein, VP4, undergoes a foldback rearrangement that translocates three clustered hydrophobic loops from one end of the molecule to the other. This conformational change resembles the foldback rearrangements of enveloped virus fusion proteins. By recoating rotavirus subviral particles with recombinant VP4 and VP7, we tested the effects on cell entry of substituting hydrophilic for hydrophobic residues in the clustered VP5 loops. Several of these mutations decreased the infectivity of recoated particles without preventing either recoating or folding back. In particular, the V391D mutant had a diminished capacity to interact with liposomes when triggered to fold back by serial protease digestion in solution, and particles recoated with this mutant VP4 were 10,000-fold less infectious than particles recoated with wild-type VP4. Particles with V391D mutant VP4 attached normally to cells and internalized efficiently, but they failed in the permeabilization step that allows coentry of the toxin alpha-sarcin. These findings indicate that the hydrophobicity of the VP5 apex is required for membrane disruption during rotavirus cell entry.

Published

2010

12. X-ray crystal structure of the rotavirus inner capsid particle at 3.8 A resolution.

Author

McClain B, Settembre E, Temple BR, Bellamy AR, and Harrison SC

Subjects

Amino Acid Sequence, Animals, Cattle, Crystallography, X-Ray, Image Processing, Computer-Assisted, Microscopy, Electron, Models, Biological, Models, Molecular, Molecular Sequence Data, Virus Assembly, Capsid chemistry, Rotavirus chemistry

Abstract

The rotavirus inner capsid particle, known as the "double-layered particle" (DLP), is the "payload" delivered into a cell in the process of viral infection. Its inner and outer protein layers, composed of viral protein (VP) 2 and VP6, respectively, package the 11 segments of the double-stranded RNA (dsRNA) of the viral genome, as well as about the same number of polymerase molecules (VP1) and capping-enzyme molecules (VP3). We have determined the crystal structure of the bovine rotavirus DLP. There is one full particle (outer diameter approximately 700 A) in the asymmetric unit of the P2(1)2(1)2(1) unit cell of dimensions a=740 A, b=1198 A, and c=1345 A. A three-dimensional reconstruction from electron cryomicroscopy was used as a molecular replacement model for initial phase determination to about 18.5 A resolution, and the 60-fold redundancy of icosahedral particle symmetry allowed phases to be extended stepwise to the limiting resolution of the data (3.8 A). The structure of a VP6 trimer (determined previously by others) fits the outer layer density with very little adjustment. The T=13 triangulation number of that layer implies that there are four and one-third VP6 trimers per icosahedral asymmetric unit. The inner layer has 120 copies of VP2 and thus 2 copies per icosahedral asymmetric unit, designated VP2A and VP2B. Residues 101-880 fold into a relatively thin principal domain, comma-like in outline, shaped such that only rather modest distortions (concentrated at two "subdomain" boundaries) allow VP2A and VP2B to form a uniform layer with essentially no gaps at the subunit boundaries, except for a modest pore along the 5-fold axis. The VP2 principal domain resembles those of the corresponding shells and homologous proteins in other dsRNA viruses: lambda1 in orthoreoviruses and VP3 in orbiviruses. Residues 1-80 of VP2A and VP2B fold together with four other such pairs into a "5-fold hub" that projects into the DLP interior along the 5-fold axis; residues 81-100 link the 10 polypeptide chains emerging from a 5-fold hub to the N-termini of their corresponding principal domains, clustered into a decameric assembly unit. The 5-fold hub appears to have several distinct functions. One function is to recruit a copy of VP1 (or of a VP1-VP3 complex), potentially along with a segment of plus-strand RNA, as a decamer of VP2 assembles. The second function is to serve as a shaft around which can coil a segment of dsRNA. The third function is to guide nascent mRNA, synthesized in the DLP interior by VP1 and 5'-capped by the action of VP3, out through a 5-fold exit channel. We propose a model for rotavirus particle assembly, based on known requirements for virion formation, together with the structure of the DLP and that of VP1, determined earlier.

Published

2010

13. A rotavirus spike protein conformational intermediate binds lipid bilayers.

Author

Trask SD, Kim IS, Harrison SC, and Dormitzer PR

Subjects

Animals, Antibodies, Neutralizing, Cell Line, Chymotrypsin, Lipid Bilayers chemistry, Liposomes chemistry, Macaca mulatta, Models, Biological, Models, Molecular, Peptide Fragments chemistry, Protein Binding, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Rotavirus genetics, Rotavirus physiology, Trypsin, Viral Nonstructural Proteins genetics, Viral Nonstructural Proteins physiology, Virus Internalization, Rotavirus chemistry, Viral Nonstructural Proteins chemistry

Abstract

During rotavirus entry, a virion penetrates a host cell membrane, sheds its outer capsid proteins, and releases a transcriptionally active subviral particle into the cytoplasm. VP5, the rotavirus protein believed to interact with the membrane bilayer, is a tryptic cleavage product of the outer capsid spike protein, VP4. When a rotavirus particle uncoats, VP5 folds back, in a rearrangement that resembles the fusogenic conformational changes in enveloped-virus fusion proteins. We present direct experimental evidence that this rearrangement leads to membrane binding. VP5 does not associate with liposomes when mounted as part of the trypsin-primed spikes on intact virions, nor does it do so after it has folded back into a stably trimeric, low-energy state. But it does bind liposomes when they are added to virions before uncoating, and VP5 rearrangement is then triggered by addition of EDTA. The presence of liposomes during the rearrangement enhances the otherwise inefficient VP5 conformational change. A VP5 fragment, VP5CT, produced from monomeric recombinant VP4 by successive treatments with chymotrypsin and trypsin, also binds liposomes only when the proteolysis proceeds in their presence. A monoclonal antibody that neutralizes infectivity by blocking a postattachment entry event also blocks VP5 liposome association. We propose that VP5 binds lipid bilayers in an intermediate conformational state, analogous to the extended intermediate conformation of enveloped-virus fusion proteins.

Published

2010

14. VP5* rearranges when rotavirus uncoats.

Author

Yoder JD, Trask SD, Vo TP, Binka M, Feng N, Harrison SC, Greenberg HB, and Dormitzer PR

Subjects

Amino Acid Sequence, Humans, Models, Molecular, Molecular Sequence Data, Rotavirus ultrastructure, Viral Nonstructural Proteins genetics, Virion metabolism, Virion ultrastructure, Virus Internalization, Protein Structure, Quaternary, Rotavirus metabolism, Viral Nonstructural Proteins chemistry, Viral Nonstructural Proteins metabolism

Abstract

Trypsin primes rotavirus for efficient infectivity by cleaving the spike protein, VP4, into VP8* and VP5*. A recombinant VP5* fragment has a trimeric, folded-back structure. Comparison of this structure with virion spikes suggests that a rearrangement, analogous to those of enveloped virus fusion proteins, may mediate membrane penetration by rotavirus during entry. To detect this inferred rearrangement of virion-associated authentic VP5*, we raised conformation-specific monoclonal antibodies against the recombinant VP5* fragment in its putative post-membrane penetration conformation. Using one of these antibodies, we demonstrate that rotavirus uncoating triggers a conformational change in the cleaved VP4 spike to yield rearranged VP5*.

Published

2009

15. Molecular interactions in rotavirus assembly and uncoating seen by high-resolution cryo-EM.

Author

Chen JZ, Settembre EC, Aoki ST, Zhang X, Bellamy AR, Dormitzer PR, Harrison SC, and Grigorieff N

Subjects

Antigens, Viral chemistry, Antigens, Viral metabolism, Antigens, Viral ultrastructure, Calcium metabolism, Capsid Proteins chemistry, Capsid Proteins metabolism, Capsid Proteins ultrastructure, Crystallography, X-Ray, Models, Biological, Models, Molecular, Protein Multimerization, Protein Structure, Quaternary, Rotavirus metabolism, Viral Core Proteins chemistry, Viral Core Proteins metabolism, Viral Core Proteins ultrastructure, Virion metabolism, Cryoelectron Microscopy methods, Rotavirus ultrastructure, Virion ultrastructure

Abstract

Rotaviruses, major causes of childhood gastroenteritis, are nonenveloped, icosahedral particles with double-strand RNA genomes. By the use of electron cryomicroscopy and single-particle reconstruction, we have visualized a rotavirus particle comprising the inner capsid coated with the trimeric outer-layer protein, VP7, at a resolution (4 A) comparable with that of X-ray crystallography. We have traced the VP7 polypeptide chain, including parts not seen in its X-ray crystal structure. The 3 well-ordered, 30-residue, N-terminal "arms" of each VP7 trimer grip the underlying trimer of VP6, an inner-capsid protein. Structural differences between free and particle-bound VP7 and between free and VP7-coated inner capsids may regulate mRNA transcription and release. The Ca(2+)-stabilized VP7 intratrimer contact region, which presents important neutralizing epitopes, is unaltered upon capsid binding.

Published

2009

16. Structure of rotavirus outer-layer protein VP7 bound with a neutralizing Fab.

Author

Aoki ST, Settembre EC, Trask SD, Greenberg HB, Harrison SC, and Dormitzer PR

Subjects

Amino Acid Sequence, Antibodies, Monoclonal chemistry, Antibodies, Monoclonal immunology, Antibodies, Monoclonal metabolism, Antibodies, Viral chemistry, Antibodies, Viral metabolism, Antigens, Viral genetics, Antigens, Viral metabolism, Binding Sites, Binding Sites, Antibody, Calcium metabolism, Capsid Proteins genetics, Capsid Proteins metabolism, Crystallography, X-Ray, Epitopes immunology, Immunoglobulin Fab Fragments chemistry, Immunoglobulin Fab Fragments metabolism, Models, Molecular, Molecular Sequence Data, Mutation, Neutralization Tests, Protein Folding, Protein Multimerization, Protein Structure, Tertiary, Protein Subunits, Recombinant Proteins chemistry, Rotavirus immunology, Serotyping, Antibodies, Viral immunology, Antigens, Viral chemistry, Antigens, Viral immunology, Capsid Proteins chemistry, Capsid Proteins immunology, Immunoglobulin Fab Fragments immunology, Rotavirus chemistry

Abstract

Rotavirus outer-layer protein VP7 is a principal target of protective antibodies. Removal of free calcium ions (Ca2+) dissociates VP7 trimers into monomers, releasing VP7 from the virion, and initiates penetration-inducing conformational changes in the other outer-layer protein, VP4. We report the crystal structure at 3.4 angstrom resolution of VP7 bound with the Fab fragment of a neutralizing monoclonal antibody. The Fab binds across the outer surface of the intersubunit contact, which contains two Ca2+ sites. Mutations that escape neutralization by other antibodies suggest that the same region bears the epitopes of most neutralizing antibodies. The monovalent Fab is sufficient to neutralize infectivity. We propose that neutralizing antibodies against VP7 act by stabilizing the trimer, thereby inhibiting the uncoating trigger for VP4 rearrangement. A disulfide-linked trimer is a potential subunit immunogen.

Published

2009

17. Mechanism for coordinated RNA packaging and genome replication by rotavirus polymerase VP1.

Author

Lu X, McDonald SM, Tortorici MA, Tao YJ, Vasquez-Del Carpio R, Nibert ML, Patton JT, and Harrison SC

Subjects

Apoenzymes chemistry, Base Sequence, Binding Sites, Models, Molecular, Nucleic Acid Conformation, Oligoribonucleotides chemistry, Protein Conformation, RNA, Viral chemistry, Rotavirus enzymology, DNA-Directed RNA Polymerases chemistry, Rotavirus genetics

Abstract

Rotavirus RNA-dependent RNA polymerase VP1 catalyzes RNA synthesis within a subviral particle. This activity depends on core shell protein VP2. A conserved sequence at the 3' end of plus-strand RNA templates is important for polymerase association and genome replication. We have determined the structure of VP1 at 2.9 A resolution, as apoenzyme and in complex with RNA. The cage-like enzyme is similar to reovirus lambda3, with four tunnels leading to or from a central, catalytic cavity. A distinguishing characteristic of VP1 is specific recognition, by conserved features of the template-entry channel, of four bases, UGUG, in the conserved 3' sequence. Well-defined interactions with these bases position the RNA so that its 3' end overshoots the initiating register, producing a stable but catalytically inactive complex. We propose that specific 3' end recognition selects rotavirus RNA for packaging and that VP2 activates the autoinhibited VP1/RNA complex to coordinate packaging and genome replication.

Published

2008

18. Structural rearrangements in the membrane penetration protein of a non-enveloped virus.

Author

Dormitzer PR, Nason EB, Prasad BV, and Harrison SC

Subjects

Amino Acid Sequence, Capsid Proteins ultrastructure, Chymotrypsin metabolism, Cryoelectron Microscopy, Models, Molecular, Molecular Sequence Data, Protein Structure, Quaternary, Protein Structure, Tertiary, Trypsin metabolism, Viral Fusion Proteins chemistry, Viral Fusion Proteins metabolism, Viral Fusion Proteins ultrastructure, Viral Proteins ultrastructure, Capsid Proteins chemistry, Capsid Proteins metabolism, Membrane Fusion, Rotavirus chemistry, Viral Proteins chemistry, Viral Proteins metabolism

Abstract

Non-enveloped virus particles (those that lack a lipid-bilayer membrane) must breach the membrane of a target host cell to gain access to its cytoplasm. So far, the molecular mechanism of this membrane penetration step has resisted structural analysis. The spike protein VP4 is a principal component in the entry apparatus of rotavirus, a non-enveloped virus that causes gastroenteritis and kills 440,000 children each year. Trypsin cleavage of VP4 primes the virus for entry by triggering a rearrangement that rigidifies the VP4 spikes. We have determined the crystal structure, at 3.2 A resolution, of the main part of VP4 that projects from the virion. The crystal structure reveals a coiled-coil stabilized trimer. Comparison of this structure with the two-fold clustered VP4 spikes in a approximately 12 A resolution image reconstruction from electron cryomicroscopy of trypsin-primed virions shows that VP4 also undergoes a second rearrangement, in which the oligomer reorganizes and each subunit folds back on itself, translocating a potential membrane-interaction peptide from one end of the spike to the other. This rearrangement resembles the conformational transitions of membrane fusion proteins of enveloped viruses.

Published

2004

19. Specificity and affinity of sialic acid binding by the rhesus rotavirus VP8* core.

Author

Dormitzer PR, Sun ZY, Blixt O, Paulson JC, Wagner G, and Harrison SC

Subjects

Animals, Carbohydrate Sequence, Macaca mulatta virology, Molecular Sequence Data, N-Acetylneuraminic Acid chemistry, Trisaccharides chemistry, Trisaccharides metabolism, N-Acetylneuraminic Acid metabolism, RNA-Binding Proteins metabolism, Receptors, Virus metabolism, Rotavirus metabolism, Viral Nonstructural Proteins metabolism

Abstract

Nuclear magnetic resonance spectroscopy demonstrates that the rhesus rotavirus hemagglutinin specifically binds alpha-anomeric N-acetylneuraminic acid with a K(d) of 1.2 mM. The hemagglutinin requires no additional carbohydrate moieties for binding, does not distinguish 3' from 6' sialyllactose, and has approximately tenfold lower affinity for N-glycolylneuraminic than for N-acetylneuraminic acid. The broad specificity and low affinity of sialic acid binding by the rotavirus hemagglutinin are consistent with this interaction mediating initial cell attachment prior to the interactions that determine host range and cell type specificity.

Published

2002

20. The rhesus rotavirus VP4 sialic acid binding domain has a galectin fold with a novel carbohydrate binding site.

Author

Dormitzer PR, Sun ZY, Wagner G, and Harrison SC

Subjects

Amino Acid Sequence, Binding Sites, Capsid physiology, Consensus Sequence, Crystallography, X-Ray, Epitopes chemistry, Evolution, Molecular, Galectins, Hemagglutinins chemistry, Hemagglutinins, Viral biosynthesis, Hemagglutinins, Viral chemistry, Hydrogen Bonding, Models, Molecular, Molecular Sequence Data, Nuclear Magnetic Resonance, Biomolecular, Peptide Fragments chemistry, Protein Binding, Protein Conformation, Protein Folding, Protein Structure, Secondary, Protein Structure, Tertiary, RNA-Binding Proteins biosynthesis, RNA-Binding Proteins chemistry, Recombinant Fusion Proteins chemistry, Rotavirus physiology, Structure-Activity Relationship, Substrate Specificity, Viral Nonstructural Proteins biosynthesis, Viral Nonstructural Proteins chemistry, Virion chemistry, Virion ultrastructure, Capsid chemistry, Capsid Proteins, Carbohydrate Metabolism, N-Acetylneuraminic Acid metabolism, Rotavirus chemistry

Abstract

Cell attachment and membrane penetration are functions of the rotavirus outer capsid spike protein, VP4. An activating tryptic cleavage of VP4 produces the N-terminal fragment, VP8*, which is the viral hemagglutinin and an important target of neutralizing antibodies. We have determined, by X-ray crystallography, the atomic structure of the VP8* core bound to sialic acid and, by NMR spectroscopy, the structure of the unliganded VP8* core. The domain has the beta-sandwich fold of the galectins, a family of sugar binding proteins. The surface corresponding to the galectin carbohydrate binding site is blocked, and rotavirus VP8* instead binds sialic acid in a shallow groove between its two beta-sheets. There appears to be a small induced fit on binding. The residues that contact sialic acid are conserved in sialic acid-dependent rotavirus strains. Neutralization escape mutations are widely distributed over the VP8* surface and cluster in four epitopes. From the fit of the VP8* core into the virion spikes, we propose that VP4 arose from the insertion of a host carbohydrate binding domain into a viral membrane interaction protein.

Published

2002

21. Near-Atomic Resolution Using Electron Cryomicroscopy and Single-Particle Reconstruction

Author

Zhang, Xing, Settembre, Ethan, Xu, Chen, Dormitzer, Philip R., Bellamy, Richard, Harrison, Stephen C., and Grigorieff, Nikolaus

Published

2008

22. Near-atomic resolution using electron cryomicroscopy and single-particle reconstruction.

Author

Xing Zhang, Settembre, Ethan, Chen Xu, Dormitzer, Philip R., Bellamy, Richard, Harrison, Stephen C., and Grigorieff, Nikolaus

Subjects

MICROBIAL proteins, CRYOMICROSCOPY, MACROMOLECULES, ROTAVIRUSES, AMINO acids, CYTOLOGY

Abstract

Electron cryomicroscopy (cryo-EM) yields images of macromolecular assemblies and their components, from which 3D structures can be determined, by using an image processing method commonly known as "single-particle reconstruction." During the past two decades, this technique has become an important tool for 3D structure determination, but it generally has not been possible to determine atomic models. In principle, individual molecular images contain high-resolution information contaminated by a much higher level of noise. In practice, it has been unclear whether current averaging methods are adequate to extract this information from the background. We present here a reconstruction, obtained by using recently developed image processing methods, of the rotavirus inner capsid particle ("double-layer particle" or DLP) at a resolution suitable for interpretation by an atomic model. The result establishes single-particle reconstruction as a high-resolution technique. We show by direct comparison that the cryo-EM reconstruction of viral protein 6 (VP6) of the rotavirus DLP is similar in clarity to a 3.8-Å resolution map obtained from x-ray crystallography. At this resolution, most of the amino acid side chains produce recognizable density. The icosahedral symmetry of the particle was an important factor in achieving this resolution in the cryo-EM analysis, but as the size of recordable datasets increases, single-particle reconstruction also is likely to yield structures at comparable resolution from samples of much lower symmetry. This potential has broad implications for structural cell biology. [ABSTRACT FROM AUTHOR]

Published

2008

23. Orthoreovirus and Aquareovirus core proteins: conserved enzymatic surfaces, but not protein–protein interfaces

Author

Kim, Jonghwa, Tao, Yizhi, Reinisch, Karin M., Harrison, Stephen C., and Nibert, Max L.

Subjects

*DOUBLE-stranded RNA, *REOVIRUSES, *ROTAVIRUSES, *RNA viruses

Abstract

Orthoreoviruses and Aquareoviruses constitute two respective genera in the family Reoviridae of double-stranded RNA viruses. Orthoreoviruses infect mammals, birds, and reptiles and have a genome comprising 10 RNA segments. Aquareoviruses infect fish and have a genome comprising 11 RNA segments. Despite these differences, recent structural and nucleotide sequence evidence indicate that the proteins of Orthoreoviruses and Aquareoviruses share many similarities. The focus of this review is on the structure and function of the Orthoreovirus core proteins λ1, λ2, λ3, and σ2, for which X-ray crystal structures have been recently reported. The homologous core proteins in Aquareoviruses are VP3, VP1, VP2, and VP6, respectively. By mapping the locations of conserved residues onto the Orthoreovirus crystal structures, we have found that enzymatic surfaces involved in mRNA synthesis are well conserved between these two groups of viruses, whereas several surfaces involved in protein–protein interactions are not well conserved. Other evidence indicates that the Orthoreovirus μ2 and Aquareovirus VP5 proteins are homologous, suggesting that VP5 is a core protein as μ2 is known to be. These findings provide further evidence that Orthoreoviruses and Aquareoviruses have diverged from a common ancestor and contribute to a growing understanding of the functions of the core proteins in viral mRNA synthesis. [Copyright &y& Elsevier]

Published

2004