Skip to main content

Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

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

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 year1. Trypsin cleavage of VP4 primes the virus for entry by triggering a rearrangement that rigidifies the VP4 spikes2. We have determined the crystal structure, at 3.2 Å 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 12 Å 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 viruses3,4,5,6.

Main

VP4 spikes on virions have ‘head’, ‘body’, ‘stalk’ and ‘foot’ regions (Fig. 1a), formed by the two VP4 trypsin cleavage fragments VP8* and VP5* (Fig. 1b). The VP8* fragment contains a globular domain, the ‘VP8* core’, which forms the head7. In some virus strains the VP8* core is a haemagglutination domain, which mediates initial cell attachment by binding sialic acid. Portions of both VP8* and VP5* make up the body. VP5* residues in the body are implicated in membrane penetration and integrin binding8,9,10. The carboxy-terminal part of VP5* forms the foot, which is buried beneath the VP7 layer, anchoring the spike. Neutralizing antibodies against rotavirus bind VP8*, VP5* and VP7 and block cell entry11. When present in the gut lumen, they protect against rotavirus gastroenteritis12. Thus, knowledge of the structural basis for cell entry can inform vaccine development.

Figure 1: Rotavirus virion structure, VP4 domains and fragments.
figure 1

a, The icosahedral virion has three layers: an inner VP2 layer, which contains the genome, polymerase and capping enzyme; a middle VP6 layer; and an outer VP7 layer. To initiate infection, a 710 Å diameter subviral particle, consisting of the inner two layers and their contents, is delivered into the cytoplasm. Head (H), body (B), stalk (S) and foot (F) regions of the VP4 spikes are indicated. The approximate two-fold axis of the head and body does not correspond to any icosahedral symmetry axis. The protruding portion of the spike is within the icosahedral asymmetric unit. The drawing is based on an electron cryomicroscopy image reconstruction30. b, Diagram illustrating the VP8* (residues M1–R231) and VP5* (A248–L776) fragments, produced by priming virions with trypsin14; the VP5CT fragment (A248–L525 to F528), produced by serially digesting soluble VP4 with chymotrypsin and trypsin13; and the VP8* core domain (L65–L224)7.

The VP5* fragment used for structure determination (VP5CT; Fig. 1b) is produced by serial chymotrypsin and trypsin cleavage of a VP4 precursor13. Expressed directly, the fragment is insoluble and probably misfolded. VP5CT has the authentic VP5* amino terminus at A248. VP4 cleavage to produce this N terminus is required to prime particles for cell entry and membrane interaction14,15. The crystal structure of VP5CT contains rhesus rotavirus (RRV) VP4 residues N252–L523. Perfect hemihedral twinning prevented use of diffraction data beyond 3.2 Å resolution in the structure determination (see Methods and Supplementary Methods).

VP5CT is a well-ordered homotrimer that resembles a folded umbrella (Fig. 2a). The ‘post’ of the umbrella is a C-terminal, α-helical, triple coiled-coil. Each of the three panels comprising the ‘shade’ of the umbrella is an N-terminal globular domain (Fig. 2b). Each globular domain packs in a groove between the α-helices of the other two subunits on the post's negatively charged outer surface (Fig. 2c). Just above the post, strands K, H, and G from each globular domain join in a continuously hydrogen-bonded β-annulus around the three-fold axis (Fig. 2a). At the top of the structure, propeller-like packing of tryptophan side chains (W262, strand B) creates an additional trimer contact. Between the β-annulus and the W262 propeller, a cavity (volume 390 Å3) centred on the three-fold axis leaves room for potential rearrangements. In full-length VP5*, the foot region (Fig. 1a), similar in mass to VP5CT, is attached to the coiled-coil.

Figure 2: VP5CT structure.
figure 2

a, Ribbon diagram of VP5CT. The trimer stands 84 Å high with a 37 Å maximum radius. The green and blue subunits depict residues I254–D519; the yellow subunit depicts residues E252–L517. Int, integrin-binding motif; MI, potential membrane interaction (F′G) loop. b, Ribbon diagram of a single VP5CT subunit (I254–L523). The colours of the secondary structure elements match those in e. c, The VP5CT surface oriented as in a and coloured by electrostatic potential: blue, positive; red, negative. Surfaces formed by residues selected in neutralizing antibody escape mutants (Supplementary Table 1) are labelled with residue numbers coloured by epitope in black text boxes: 5-1, yellow; 5-2, white; 5-3, green; 5-4, pink; 5-5, orange. I254, L517 and D519 mark N- and C termini of the depicted subunits. D308, G309 and E310 form the integrin-binding motif at the tip of the claw-like CD hairpin. d, The VP5CT surface, coloured as in c and viewed along the three-fold symmetry axis from the bottom. Surfaces formed by hydrophobic residues at the apex of the globular domain are labelled on the upper-left subunit. e, Secondary structure assigned to the RRV primary amino acid sequence. β-strands are arrows; the α-helix is a tube. Variable secondary structure at the N- and C termini is indicated by dashed outlines. Blue letters indicate neutralization escape mutations; escape mutations in strain RRV are boxed8. The green underline identifies the integrin-binding motif10. The red underline identifies the potential membrane interaction loop8. Residues that make hydrophobic contacts around the three-fold axis of the coiled-coil are indicated by ‘a’ or ‘d’, corresponding to heptad repeat positions.

The core of each globular domain is an eight-stranded anti-parallel β-sandwich (Fig. 2b, light and dark blue). Two features of potential functional importance project from its top edge: the GH and CD β-hairpins. By joining with strands K in the β-annulus, the GH hairpin clamps each globular domain in the ‘folded umbrella’ position. The flexible tip of the CD β-hairpin bears a sequence motif (DGE) implicated in rotavirus binding to α2β1 integrins (Fig. 2b, e)10. The accessibility of the motif, which protrudes into solvent, supports the proposed receptor-binding function.

The tips of loops projecting from the bottom edge of the β-sandwich impart a hydrophobic apex to the globular domain (Fig. 2d), which may function in membrane penetration. Near the β-sandwich, portions of these loops form β-sheets F′G(H/H′) and B′C′E′D′ (purple and pink respectively in Fig. 2b). The unusual interposition of β-strand I (green) between these sheets creates a deep ‘hydrophobic bowl’. The distal part of the F′G loop and the alphavirus ‘fusion loop’ have similar sequences8. Both loops lie at the hydrophobic tips of globular domains implicated in membrane disruption, but the domains and the loops themselves are otherwise structurally dissimilar (Supplementary Fig. 1 and Tables 2, 3)6. Thus, the sequence similarity probably reflects selection for hydrophobicity and flexibility in both loops, but not common ancestry. Each strand of the F′G loop has an in-register glycine–glycine pair (382–383 and 399–400, located under labels F′ and G in Fig. 2b). The four conserved glycines might provide a hinge, opening up the hydrophobic bowl beneath and allowing relatively extensive and flexible membrane interactions during cell entry.

How does the VP5CT structure relate to that of the VP4 spike? The region of VP5CT from Y267 to L470 neatly fits the molecular envelope of the spike body in a new, 12 Å resolution electron cryomicroscopy image reconstruction of trypsin-primed virions (Fig. 3b, e). As Y267 and L470 hydrogen bond to each other on adjacent β-strands B and J, this region constitutes a self-contained globular domain called the VP5* antigen domain (solid colours in Fig. 3c, f). VP5CT residues outside the antigen domain must fold differently in the spike than in the trimeric crystal structure (white outlines in Fig. 3c, f).

Figure 3: The VP5* antigen domain and the VP8* core fit to an electron cryomicroscopy image reconstruction.
figure 3

Each model in df is rotated 90° about a vertical axis relative to the corresponding model in ac. a, d, Surface models oriented as in the spike. The surfaces are coloured by conservation in 20 P genotypes (sequences referenced in Supplementary Table 2): blue, conserved; red, variable. Neutralization epitopes are outlined: 5-1, solid yellow; 5-2, solid white; 5-3, solid green; 5-4, solid pink; 5-5, solid orange; 8-1, dashed yellow; 8-2, dashed white; 8-3, dashed green; 8-4, dashed pink. VP8* epitopes and the sialoside-binding site (red asterisk) have been described previously7. b, e, Cα traces of the VP8* core and VP5* antigen domain fit to an image reconstruction of trypsinized virions at 12 Å resolution, contoured at 0.45σ. Labelled residues: 65 and 224, VP8* core termini; 267 and 470, VP5* antigen domain termini; 309, glycine of the DGE integrin-binding motif (CD loop); 393, immunodominant site in the potential membrane interaction (F′G) loop; 417, tip of the GH hairpin. c, f, Ribbon diagrams of the VP5CT subunit, with the antigen domain oriented to fit the spike body. The antigen domain is coloured to match Fig. 2b. Residues outside the antigen domain, which must fold differently in the spike, are drawn in white outline.

Together, the VP5* antigen domain and the VP8* core contain all known neutralizing epitopes on VP4 (Fig. 3a, d), making them logical minimal antigens for recombinant rotavirus vaccines. The much greater conservation in VP5* suggests stronger functional constraints and correlates with heterotypic neutralization by some VP5*-specific antibodies. The VP5* antigen domain is thus a particularly promising potential immunogen. On the basis of the VP5CT structure, we have grouped VP5* neutralization escape mutations into five epitopes (Supplementary Table 1). The epitopes are solvent-exposed on both the VP5CT trimer (Fig. 2c, d) and the spike body (Fig. 3a, d). The surfaces of the trimer that lack neutralization epitopes are inaccessible on the spike, explaining their antigenic ‘silence’ on primed virions.

Most VP5*-specific neutralizing monoclonal antibodies map to epitope 5-1, the exposed surface of the ‘shoulder’ at the virion-distal end of the spike body, formed by the hydrophobic apex of the antigen domain (Fig. 3). The head covers much of the apex, but part of the F′G loop is exposed. Monoclonal antibody 2G4 selects a neutralization escape mutation in this loop at residue Q393 (ref. 8). Electron cryomicroscopy of antibody-binding fragment (FAb)-decorated virions shows that 2G4 indeed binds the shoulder16, confirming our fit of the antigen domain to the spike body. Antibody 2G4 blocks a post-attachment entry event11, which is possibly domain rotation or membrane insertion (see below). Epitopes 5-1, 5-2, 5-3 and 5-4 are linked by a network of antibody competition and escape mutant cross-resistance (references in Supplementary Table 1). Epitope 5-5 is outside of this network and is mimicked by a short synthetic peptide17. It maps to the flexible CD hairpin, adjacent to the integrin-binding motif (Fig. 2b, c, e), suggesting that epitope 5-5-specific antibodies may block integrin interactions.

Image reconstructions from electron cryomicroscopy of rotavirus particles have provided good evidence for two conformational states of VP4: an uncleaved, flexible state, which does not produce visible density in averaged image reconstructions2 (Fig. 4a), and a trypsin-cleaved, rigid state with approximate two-fold symmetry of the parts that project beyond the VP7 shell (Figs 3b, e and 4b)18,19. Contrary to the two-fold character of the projecting part of the spikes on trypsin-primed virions, the VP5CT crystal structure reveals an unambiguous trimer (Fig. 2a, c, d). The three-fold contacts bury 3,956 Å2 (25.8%) of the surface of each subunit and render the trimer resistant to dissociation by SDS13. Such extensive and stable contacts provide structural evidence that this region of VP4 evolved to trimerize. VP5CT thus represents a third conformational state for the projecting part of VP4 (Fig. 4c).

Figure 4: Model for VP4 rearrangements during priming and entry.
figure 4

The colours in the cartoon (ac) match those in the linear diagram (d). The VP7 shell is blue. a, Uncleaved state. The wavy lines indicate flexibility. b, Trypsin-primed state. The activation region (brown in a) between VP8* and VP5* has been removed by digestion. Two clustered molecules form the visible spike. The head is the yellow oval (the VP8* core), notched at the sialoside-binding cleft. The body includes the red ‘kidney’ (the VP5* antigen domain), the orange cap (the potential membrane interaction loop), the purple appendage, and part of the grey and cyan tubes. The stalk is the lower part of the cyan tubes. The foot is the green hexagonal prism. c, Folded-back state. This state corresponds to the VP5CT crystal structure and may form during membrane penetration. The dashed blue line indicates potential loss of VP7. d, Linear diagram of structural elements. The VP8* and VP5* fragments are in black boxes. Grey, residues M1–V64; yellow, L65–L224; pink, P225–R231; brown, N232–R247; purple, A248–Q266; red, Y267–T381 and A401–L470; orange, G382–G400; cyan, I471–unknown; green, unknown–L776.

How can a two-fold to three-fold reorganization of VP4 occur? For the transition to take place on the virion, rather than after dissociation, each spike location must actually contain three VP4 subunits at all stages. Indeed, recently obtained image reconstructions of trypsinized rotavirus particles treated briefly at pH 11 reveal foreshortened spikes with clear three-fold character: trefoil-like features projecting slightly above the VP7 layer (B.V.V.P., manuscript in preparation). Unfolding at elevated pH appears to cause each VP4 subunit to condense so that better-ordered segments near the foot produce strong density in the image. We conclude that two-fold clustering after trypsin cleavage leaves the third subunit still flexible, as in the uncleaved state (Fig. 4b).

Several observations support this view of VP4 organization. The spike projects from an asymmetric, angled stalk, so that its approximate two-fold axis is displaced from the centre of the foot18,19. Thus, the symmetry of the foot and the projecting spike need not match. Indeed, image reconstructions of VP4 obtained by subtracting images of spikeless particles from images of particles with spikes reveal three-fold symmetry in the foot19. The symmetry mismatch between foot and projection was previously reconciled by proposing that two VP4 subunits each contribute three similarly shaped domains to the foot. The new data suggest, instead, that the three-fold symmetry of the foot reflects the true subunit stoichiometry. Our previous biochemical data on VP5CT oligomers in solution were consistent either with trimers or with tight dimers that associate weakly into tetramers (dimers of dimers)13. At the time, the latter interpretation appeared more consistent with electron microscopy, but the crystal structure and new image reconstructions resolve the ambiguity in favour of trimers.

If just two of three VP4 subunits at each spike location cluster after trypsin cleavage, interactions with VP7 and/or VP6 must select the two that form the visible spike. The VP8* and VP5* fragments of the third, flexible molecule need not remain associated, and this subunit could even perform a different function in cell entry. Interactions with VP7 and VP6 may also arrest the progression of VP4 rearrangements at the primed stage.

In the dimeric spike, a loop (F′G) with the properties of a membrane-interacting element points away from the foot, and the GH hairpin points approximately 90° away from the dyad axis of the body (Fig. 3b, c, e, f). In the VP5CT trimer, the F′G loop points towards the C terminus of the coiled-coil, to which the stalk and foot attach, and the GH hairpin joins the β-annulus around the three-fold axis (Fig. 2a). Therefore, in the two-fold to three-fold reorganization, the VP5* antigen domain must rotate approximately 180° about an axis roughly perpendicular to the spike's long axis (Fig. 4b, c). This rotation translocates the hydrophobic tip of the F′G loop by at least 55 Å from the shoulder of the spike towards the foot.

The two subunits of the spike body make proximal and distal dyad contacts, leaving a gap in the centre (Fig. 3b, e). The VP4 residues that participate in these contacts are outside the relatively rigid VP8* core and VP5* antigen domain and probably control their large-scale displacements. Both termini of the VP8* core are in the ‘neck’ between head and body, near the distal dyad contact. Both termini of the VP5* antigen domain are at the bottom of the body, adjacent to the proximal dyad contact. The antigen domain completely fills the electron microscopy envelope between the dyad contacts, leaving no unfilled density to suggest an unmodelled connecting strand. Therefore, VP8* residues outside the core (M1–V64) must form the distal dyad contact and tether head to body. During rotation of the VP5* antigen domain, disruption of the distal dyad contact would release VP8* (Fig. 4c). Similarly, VP5* residues outside the antigen domain (A248–Q266 and I471–L523 and perhaps additional C-terminal residues that connect to the stalk) must form the proximal dyad contact. In the trimeric state, these residues make up the elements of the three-fold contacts: β-sheet ABJ, β-strand K and the α-helix (Figs 2a and 3c, f). The refolding of residues in the proximal dyad contact to form the coiled-coil may drive the two-fold to three-fold reorganization.

The three distinct conformations of VP4 correspond to steps in rotavirus entry (Fig. 4a–d). When uncleaved virions are released from infected cells, three VP4 molecules with flexible stalks occupy each of 60 symmetry-equivalent positions (Fig. 4a). In the gut lumen, trypsin cleavage between VP8* and VP5* produces a first rearrangement, which primes VP5* for membrane attack (Fig. 4b). Dimeric interactions in the external portion of two primed VP4 subunits rigidify the spikes, elevating and presenting the VP8* core for cell-surface ligand binding. The third VP4 molecule remains flexible. The heads of the spike shield hydrophobic prominences on the body. We hypothesize that a subsequent, as yet unknown, entry-associated event triggers a transition to the trimeric conformation seen in the crystal structure (Fig. 4c). In this second transition, disruption of the dimer contacts releases VP8* from VP5* and unmasks the hydrophobic apex of the VP5* antigen domain, which may insert into a host-cell membrane. As the trimeric coiled-coil zips up, the antigen domain folds back against it. The resulting translocation of the potential membrane-interaction loop towards the foot could disrupt a cellular membrane. This disruption may in turn create a breach that allows a subviral particle to enter the cytoplasm, or it could lower the local calcium concentration, leading to virion uncoating and subsequent entry events. The fold-back transition could also alter interactions with receptors or directly trigger virion uncoating.

The essential properties of VP4—its capacity to adopt an inactive, precursor conformation; a primed, receptor-binding conformation; and a final, folded-back conformation—recall those of enveloped virus fusion proteins3,4,5,6. Understanding these transformations will allow us to analyse neutralization mechanisms, design subunit immunogens, and elucidate molecular details of membrane perforation.

Methods

Expression and purification of RRV VP5CT

VP5CT was produced by serial chymotrypsin and trypsin digestion of purified RRV VP4 from recombinant baculovirus-infected insect cells, as described previously13. Selenomethionine-substituted protein was produced by metabolic incorporation in insect cells20.

Crystallization

VP5CT crystallized at 23 °C in hanging drops containing equal volumes of well solutions and a protein solution containing 9 mg ml-1 VP5CT, 20 mM Tris, pH 8.0, 1 mM EDTA, 0.02% sodium azide and 0.1 mM benzamidine. Selenomethionine-substituted VP5CT crystals that formed after 4 days with a well solution of 6% ethanol, 50 mM Tris pH 7.0 and 1 mM dithiothreitol were harvested after one month and flash-frozen with liquid nitrogen in a freezing buffer of 11% ethanol, 50 mM Tris, pH 7.0, 17% 2-methyl-2,4-pentanediol (MPD) and 5 mM dithiothreitol. Unsubstituted VP5CT crystals that formed after 3 weeks with a well solution of 500 mM ammonium sulphate, 5.5–6% MPD and 50 mM PIPES pH 6.5 were harvested after 1–7 months and flash-frozen in 600 mM ammonium sulphate, 22.5% MPD and 20–50 mM Tris, pH 8.0.

Structure determination

Diffraction data were scaled in space group P4(2)22, with six monomers per asymmetric unit. Starting phases were determined by multiple wavelength anomalous dispersion, based on diffraction from crystals of selenomethionine-substituted VP5CT. Thirty seleniums per asymmetric unit were located by direct methods, using SnB21. Landmarks provided by seleniums and bulky side chains unambiguously aligned the primary amino acid sequence to the electron density. Refinement took advantage of six-fold non-crystallographic symmetry. The final model contains no Ramachandran violations, and 76.6% of dihedral angles are in most-favoured regions. Pseudocentring and perfect hemihedral twinning in VP5CT crystals has been described previously22. Details of the structure determination are provided in Supplementary Methods, Supplementary Table 4, and Supplementary Fig. 2.

Electron cryomicroscopy

Electron micrographs of rotavirus particles (strain SA11-4F) embedded in a thin layer of vitreous ice were recorded under low electron dose conditions ( 10 e- Å-2) at ×50,000 magnification on a JEOL 4000 electron microscope operated at 400 kV. Electron micrographs were digitized with a scanning interval corresponding to 2.8 Å in the object. A three-dimensional reconstruction was computed using cylindrical expansion methods23,24 to 12.4 Å resolution by combining 908 particles from 15 micrographs with appropriate corrections for contrast transfer function. Defocus values, determined using EMAN software25, ranged from 0.8 to 3-µm underfocus. As is conventional23, to compute initial maps, electron microscopy data were first analysed in reciprocal space, using only 5-2-2 symmetry. To compute the final map, full icosahedral symmetry was imposed by three-fold real-space averaging after confirming the presence of three-fold symmetry in initial maps. The protruding portion of the VP4 spike was computationally extracted from the final density map. Crystal structures were fit to the electron cryomicroscopy map by a combination of automated searching using Situs26 and manual fitting.

Illustration

Figures were made using O27, Molscript28, Grasp29, Photoshop (Adobe Systems) and Illustrator (Adobe Systems).

References

  1. Parashar, U. D., Hummelman, E. G., Bresee, J. S., Miller, M. A. & Glass, R. I. Global illness and deaths caused by rotavirus disease in children. Emerg. Infect. Dis. 9, 565–572 (2003)

    Article  Google Scholar 

  2. Crawford, S. E. et al. Trypsin cleavage stabilizes the rotavirus VP4 spike. J. Virol. 75, 6052–6061 (2001)

    CAS  Article  Google Scholar 

  3. Ruigrok, R. W. et al. Studies on the structure of the influenza virus haemagglutinin at the pH of membrane fusion. J. Gen. Virol. 69, 2785–2795 (1988)

    CAS  Article  Google Scholar 

  4. Weissenhorn, W. et al. The ectodomain of HIV-1 env subunit gp41 forms a soluble, alpha-helical, rod-like oligomer in the absence of gp120 and the N-terminal fusion peptide. EMBO J. 15, 1507–1514 (1996)

    CAS  Article  Google Scholar 

  5. Modis, Y., Ogata, S., Clements, D. & Harrison, S. C. Structure of the dengue virus envelope protein after membrane fusion. Nature 427, 313–319 (2004)

    ADS  CAS  Article  Google Scholar 

  6. Gibbons, D. L. et al. Conformational change and protein-protein interactions of the fusion protein of Semliki Forest virus. Nature 427, 320–325 (2004)

    ADS  CAS  Article  Google Scholar 

  7. Dormitzer, P. R., Sun, Z.-Y. J., Wagner, G. & Harrison, S. C. The rhesus rotavirus VP4 sialic acid binding domain has a galectin fold with a novel carbohydrate binding site. EMBO J. 21, 885–897 (2002)

    CAS  Article  Google Scholar 

  8. Mackow, E. R. et al. The rhesus rotavirus gene encoding protein VP3: location of amino acids involved in homologous and heterologous rotavirus neutralization and identification of a putative fusion region. Proc. Natl Acad. Sci. USA 85, 645–649 (1988)

    ADS  CAS  Article  Google Scholar 

  9. Dowling, W., Denisova, E., LaMonica, R. & Mackow, E. R. Selective membrane permeabilization by the rotavirus VP5* protein is abrogated by mutations in an internal hydrophobic domain. J. Virol. 74, 6368–6376 (2000)

    CAS  Article  Google Scholar 

  10. Graham, K. L. et al. Integrin-using rotaviruses bind α2β1 integrin α2 I domain via VP4 DGE sequence and recognize αXβ2 and αVβ3 by using VP7 during cell entry. J. Virol. 77, 9969–9978 (2003)

    CAS  Article  Google Scholar 

  11. Ruggeri, F. M. & Greenberg, H. B. Antibodies to the trypsin cleavage peptide VP8 neutralize rotavirus by inhibiting binding of virions to target cells in culture. J. Virol. 65, 2211–2219 (1991)

    CAS  PubMed  PubMed Central  Google Scholar 

  12. Offit, P. A., Shaw, R. D. & Greenberg, H. B. Passive protection against rotavirus-induced diarrhea by monoclonal antibodies to surface proteins vp3 and vp7. J. Virol. 58, 700–703 (1986)

    CAS  PubMed  PubMed Central  Google Scholar 

  13. Dormitzer, P. R., Greenberg, H. B. & Harrison, S. C. Proteolysis of monomeric recombinant rotavirus VP4 yields an oligomeric VP5* core. J. Virol. 75, 7339–7350 (2001)

    CAS  Article  Google Scholar 

  14. Arias, C. F., Romero, P., Alvarez, V. & Lopez, S. Trypsin activation pathway of rotavirus infectivity. J. Virol. 70, 5832–5839 (1996)

    CAS  PubMed  PubMed Central  Google Scholar 

  15. Gilbert, J. M. & Greenberg, H. B. Cleavage of rhesus rotavirus VP4 after arginine 247 is essential for rotavirus-like particle-induced fusion from without. J. Virol. 72, 5323–5327 (1998)

    CAS  PubMed  PubMed Central  Google Scholar 

  16. Tihova, M., Dryden, K. A., Bellamy, A. R., Greenberg, H. B. & Yeager, M. Localization of membrane permeabilization and receptor binding sites on the VP4 hemagglutinin of rotavirus: implications for cell entry. J. Mol. Biol. 314, 985–992 (2001)

    CAS  Article  Google Scholar 

  17. Taniguchi, K. et al. Identification of cross-reactive and serotype 2-specific neutralization epitopes on VP3 of human rotavirus. J. Virol. 62, 2421–2426 (1988)

    CAS  PubMed  PubMed Central  Google Scholar 

  18. Shaw, A. L. et al. Three-dimensional visualization of the rotavirus hemagglutinin structure. Cell 74, 693–701 (1993)

    CAS  Article  Google Scholar 

  19. Yeager, M., Berriman, J. A., Baker, T. S. & Bellamy, A. R. Three-dimensional structure of the rotavirus haemagglutinin VP4 by cryo-electron microscopy and difference map analysis. EMBO J. 13, 1011–1018 (1994)

    CAS  Article  Google Scholar 

  20. Liemann, S., Chandran, K., Baker, T. S., Nibert, M. L. & Harrison, S. C. Structure of the reovirus membrane-penetration protein, µ1, in a complex with its protector protein, σ3. Cell 108, 283–295 (2002)

    CAS  Article  Google Scholar 

  21. Weeks, C. M. & Miller, R. The design and implementation of SnB v2.0. J. Appl. Crystallogr. 32, 120–124 (1999)

    CAS  Article  Google Scholar 

  22. Padilla, J. E. & Yeates, T. O. A statistic for local intensity differences: robustness to anisotropy and pseudo-centering and utility for detecting twinning. Acta Crystallogr. D 59, 1124–1130 (2003)

    Article  Google Scholar 

  23. Crowther, R. A. Procedures for three-dimensional reconstruction of spherical viruses by Fourier synthesis from electron micrographs. Phil. Trans. R. Soc. Lond. B 261, 221–230 (1971)

    ADS  CAS  Article  Google Scholar 

  24. Lawton, J. A. & Prasad, B. V. V. Automated software package for icosahedral virus reconstruction. J. Struct. Biol. 116, 209–215 (1996)

    CAS  Article  Google Scholar 

  25. Ludtke, S. J., Baldwin, P. R. & Chiu, W. EMAN: semiautomated software for high-resolution single-particle reconstructions. J. Struct. Biol. 128, 82–97 (1999)

    CAS  Article  Google Scholar 

  26. Wriggers, W., Milligan, R. A. & McCammon, J. A. Situs: A package for docking crystal structures into low-resolution maps from electron microscopy. J. Struct. Biol. 125, 185–195 (1999)

    CAS  Article  Google Scholar 

  27. Jones, T. A., Zou, J. Y., Cowan, S. W. & Kjeldgaard, M. Improved methods for binding protein models in electron density maps and the location of errors in these models. Acta Crystallogr. A 47, 110–119 (1991)

    Article  Google Scholar 

  28. Kraulis, J. MOLSCRIPT: A program to produce both detailed and schematic plots of protein structures. J. Appl. Crystallogr. 24, 946–950 (1991)

    Article  Google Scholar 

  29. Nicholls, A., Sharp, K. A. & Honig, B. Protein folding and association: insights from interfacial and thermodynamic properties of hydrocarbons. Prot. Struct. Funct. Genet. 11, 281–296 (1991)

    CAS  Article  Google Scholar 

  30. Yeager, M., Dryden, K. A., Olson, N. H., Greenberg, H. B. & Baker, T. S. Three-dimensional structure of rhesus rotavirus by cryoelectron microscopy and image reconstruction. J. Cell Biol. 110, 2133–2144 (1990)

    CAS  Article  Google Scholar 

Download references

Acknowledgements

We thank M. Babyonyshev for technical assistance; T. Yeates for help in analysing the crystal twinning disorder; H. Greenberg for cloned genes and recombinant baculoviruses; E. Vogan for help with data collection and analysis; and the staff of Advanced Photon Source beamline ID-19 (Argonne National Laboratory) and Cornell High Energy Synchrotron Source beamlines F1 and A1. We acknowledge the use of electron cryomicroscopy facilities at the National Center for Macromolecular Imaging funded by NIH at Baylor College of Medicine. This work was supported by an NIH grant and an Ellison Medical Foundation New Investigator in Global Infectious Diseases award to P.R.D., by an NIH grant to B.V.V.P., and by an NIH grant to S.C.H., who is a Howard Hughes Medical Institute Investigator.

Author information

Authors and Affiliations

Authors

Corresponding author

Correspondence to Philip R. Dormitzer.

Ethics declarations

Competing interests

The authors declare that they have no competing financial interests.

Supplementary information

Supplementary Figure 1

Comparison of the rotavirus VP4 F'G loop and the alphavirus E1 fusion loop. Includes an amino acid sequence comparison and a structural comparison. (PDF 158 kb)

Supplementary Figure 2

Sample of electron density. An image from an unaveraged simulated annealing omit map is shown. (PDF 1474 kb)

Supplementary Methods

Details of the crystallographic structure determination. Includes a description of the twinning disorder in the crystals. (DOC 35 kb)

Supplementary Table 1

Neutralization escape mutations. Mutations that map to the VP5* fragment are assigned to epitopes based on the VP5CT structure. (DOC 62 kb)

Supplementary Table 2

Rotavirus VP4 sequences used to assess variability and obtain a consensus sequence. The variability in these sequences is mapped onto the surfaces of the VP8* core and VP5* antigen domain in Fig. 3a, c. The consensus sequence is used to assess the similarity between the VP4 F'G loop and the alphavirus E1 fusion loop in Supplementary Fig. 1. (DOC 37 kb)

Supplementary Table 3

Alphavirus E1 sequences used to obtain a consensus. The consensus sequence is used to assess the similarity between the VP4 F'G loop and the alphavirus E1 fusion loop in Supplementary Fig. 1. (DOC 26 kb)

Supplementary Table 4

X-ray diffraction data collection, phasing, and refinement statistics. (DOC 47 kb)

Rights and permissions

Reprints and Permissions

About this article

Cite this article

Dormitzer, P., Nason, E., Venkataram Prasad, B. et al. Structural rearrangements in the membrane penetration protein of a non-enveloped virus. Nature 430, 1053–1058 (2004). https://doi.org/10.1038/nature02836

Download citation

  • Received:

  • Accepted:

  • Issue Date:

  • DOI: https://doi.org/10.1038/nature02836

Further reading

Comments

By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.

Search

Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing