Chimeric calicivirus-like particles elicit protective anti-viral cytotoxic responses without adjuvant.

We have analyzed the potential of virus-like particles (VLPs) from rabbit hemorrhagic disease virus (RHDV) as a delivery system for foreign T cell epitopes. To accomplish this goal, we generated chimeric RHDV-VLPs incorporating a CD8(+) T cell epitope (SIINFEKL) derived from chicken ovalbumin (OVA). The OVA epitope was inserted in the capsid protein (VP60) of RHDV at two different locations: 1) the N-terminus, predicted to be facing to the inner core of the VLPs, and 2) a novel insertion site predicted to be located within an exposed loop. Both constructions correctly assembled into VLPs. In vitro, the chimeric VLPs activated dendritic cells for TNF-alpha secretion and they were processed and presented to specific T cells. In vivo, mice immunized with the chimeric VLPs without adjuvant were able to induce specific cellular responses mediated by cytotoxic and memory T cells. More importantly, immunization with chimeric VLPs was able to resolve an infection by a recombinant vaccinia virus expressing OVA protein.

Sharpening high resolution information in single particle electron cryomicroscopy.

Advances in single particle electron cryomicroscopy have made possible to elucidate routinely the structure of biological specimens at subnanometer resolution. At this resolution, secondary structure elements are discernable by their signature. However, identification and interpretation of high resolution structural features are hindered by the contrast loss caused by experimental and computational factors. This contrast loss is traditionally modeled by a Gaussian decay of structure factors with a temperature factor, or B-factor. Standard restoration procedures usually sharpen the experimental maps either by applying a Gaussian function with an inverse ad hoc B-factor, or according to the amplitude decay of a reference structure. EM-BFACTOR is a program that has been designed to widely facilitate the use of the novel method for objective B-factor determination and contrast restoration introduced by Rosenthal and Henderson [Rosenthal, P.B., Henderson, R., 2003. Optimal determination of particle orientation, absolute hand, and contrast loss in single-particle electron cryomicroscopy. J. Mol. Biol. 333, 721-745]. The program has been developed to interact with the most common packages for single particle electron cryomicroscopy. This sharpening method has been further investigated via EM-BFACTOR, concluding that it helps to unravel the high resolution molecular features concealed in experimental density maps, thereby making them better suited for interpretation. Therefore, the method may facilitate the analysis of experimental data in high resolution single particle electron cryomicroscopy.

C terminus of infectious bursal disease virus major capsid protein VP2 is involved in definition of the T number for capsid assembly.

Infectious bursal disease virus (IBDV), a member of the Birnaviridae family, is a double-stranded RNA virus. The IBDV capsid is formed by two major structural proteins, VP2 and VP3, which assemble to form a T=13 markedly nonspherical capsid. During viral infection, VP2 is initially synthesized as a precursor, called VPX, whose C end is proteolytically processed to the mature form during capsid assembly. We have computed three-dimensional maps of IBDV capsid and virus-like particles built up by VP2 alone by using electron cryomicroscopy and image-processing techniques. The IBDV single-shelled capsid is characterized by the presence of 260 protruding trimers on the outer surface. Five classes of trimers can be distinguished according to their different local environments. When VP2 is expressed alone in insect cells, dodecahedral particles form spontaneously; these may be assembled into larger, fragile icosahedral capsids built up by 12 dodecahedral capsids. Each dodecahedral capsid is an empty T=1 shell composed of 20 trimeric clusters of VP2. Structural comparison between IBDV capsids and capsids consisting of VP2 alone allowed the determination of the major capsid protein locations and the interactions between them. Whereas VP2 forms the outer protruding trimers, VP3 is found as trimers on the inner surface and may be responsible for stabilizing functions. Since elimination of the C-terminal region of VPX is correlated with the assembly of T=1 capsids, this domain might be involved (either alone or in cooperation with VP3) in the induction of different conformations of VP2 during capsid morphogenesis.

Different architectures in the assembly of infectious bursal disease virus capsid proteins expressed in insect cells.

Infectious bursal disease virus (IBDV) capsid is formed by the processing of a large polyprotein and subsequent assembly of VPX/VP2 and VP3. To learn more about the processing of the polyprotein and factors affecting the correct assembly of the viral capsid in vitro, different constructs were made using two baculovirus transfer vectors, pFastBac and pAcYM1. Surprisingly, the expression of the capsid proteins gave rise to different types of particles in each system, as observed by electron microscopy and immunofluorescence. FastBac expression led to the production of only rigid tubular structures, similar to those described as type I in viral infection. Western blot analysis revealed that these rigid tubules are formed exclusively by VPX. These tubules revealed a hexagonal arrangement of units that are trimer clustered, similar to those observed in IBDV virions. In contrast, pAcYM1 expression led to the assembly of virus-like particles (VLPs), flexible tubules, and intermediate assembly products formed by icosahedral caps elongated in tubes, suggesting an aberrant morphogenesis. Processing of VPX to VP2 seems to be a crucial requirement for the proper morphogenesis and assembly of IBDV particles. After immunoelectron microscopy, VPX/VP2 was detected on the surface of tubules and VLPs. We also demonstrated that VP3 is found only on the inner surfaces of VLPs and caps of the tubular structures. In summary, assembly of VLPs requires the internal scaffolding of VP3, which seems to induce the closing of the tubular architecture into VLPs and, thereafter, the subsequent processing of VPX to VP2.

Topology of the components of the DNA packaging machinery in the phage phi29 prohead.

Chromosome condensation inside dsDNA viral particles is a complex process requiring the coordinated action of several viral components. The similarity of the process in different viral systems has led to the suggestion that there is a common underlying mechanism for DNA packaging, in which the portal vertex or connector plays a key role. We have studied the topology of the packaging machinery using a number of antibodies directed against different domains of the connector. The charged amino-terminal, the carboxyl-terminal, and the RNA binding domain are accessible areas in the connector assembled into the prohead, while the domains corresponding to the 12 large appendages of the connector are buried inside the prohead. Furthermore, while the antibodies against the carboxyl and amino-terminal do not affect the packaging reaction, incubation of proheads with antibodies against the RNA binding domain abolishes the packaging activity. The comparison of the three-dimensional reconstructions of bacteriophage phi29 proheads with proheads devoid of their specific pRNA by RNase treatment shows that this treatment removes structural elements of the distal vertex of the portal structure, suggesting that the pRNA required for packaging is located at the open gate of the channel in the narrow side of the connector.

VP1, the putative RNA-dependent RNA polymerase of infectious bursal disease virus, forms complexes with the capsid protein VP3, leading to efficient encapsidation into virus-like particles.

A cDNA corresponding to the coding region of VP1, the putative RNA-dependent RNA polymerase, of infectious bursal disease virus (IBDV) was cloned and inserted into the genome of a vaccinia virus inducible expression vector. The molecular mass and antigenic reactivity of VP1 expressed in mammalian cells are identical to those of its counterpart expressed in IBDV-infected cells. The results presented here demonstrate that VP1 is efficiently incorporated into IBDV virus-like particles (VLPs) produced in mammalian cells coexpressing the IBDV polyprotein and VP1. Incorporation of VP1 into VLPs requires neither the presence of IBDV RNAs nor that of the nonstructural polypeptide VP5. Immunofluorescence, confocal laser scanning microscopy, and immunoprecipitation analyses conclusively showed that VP1 forms complexes with the structural polypeptide VP3. Formation of VP1-VP3 complexes is likely to be a key step for the morphogenesis of IBDV particles.

A strategy for determining the orientations of refractory particles for reconstruction from cryo-electron micrographs with particular reference to round, smooth-surfaced, icosahedral viruses.

Cryo-electron microscopy and three-dimensional image reconstruction are powerful tools for analyzing icosahedral virus capsids at resolutions that now extend below 1 nm. However, the validity of such density maps depends critically on correct identification of the viewing geometry of each particle in the data set. In some cases-for example, round capsids with low surface relief-it is difficult to identify orientations by conventional application of the two most widely used approaches-"common lines" and model-based iterative refinement. We describe here a strategy for determining the orientations of such refractory specimens. The key step is to determine reliable orientations for a base set of particles. For each particle, a list of candidate orientations is generated by common lines: correct orientations are then identified by computing a single-particle reconstruction for each candidate and then systematically matching their reprojections with the original images by visual criteria and cross-correlation analysis. This base set yields a first-generation reconstruction that is fed into the model-based procedure. This strategy has led to the structural determination of two viruses that, in our hands, resisted solution by other means.

Structure of L-A virus: a specialized compartment for the transcription and replication of double-stranded RNA.

The genomes of double-stranded (ds)RNA viruses are never exposed to the cytoplasm but are confined to and replicated from a specialized protein-bound compartment-the viral capsid. We have used cryoelectron microscopy and three-dimensional image reconstruction to study this compartment in the case of L-A, a yeast virus whose capsid consists of 60 asymmetric dimers of Gag protein (76 kD). At 16-A resolution, we distinguish multiple domains in the elongated Gag subunits, whose nonequivalent packing is reflected in subtly different morphologies of the two protomers. Small holes, 10-15 A across, perforate the capsid wall, which functions as a molecular sieve, allowing the exit of transcripts and the influx of metabolites, while retaining dsRNA and excluding degradative enzymes. Scanning transmission electron microscope measurements of mass-per-unit length suggest that L-A RNA is an A-form duplex, and that RNA filaments emanating from disrupted virions often consist of two or more closely associated duplexes. Nuclease protection experiments confirm that the genome is entirely sequestered inside full capsids, but it is packed relatively loosely; in L-A, the center-to-center spacing between duplexes is 40-45 A, compared with 25-30 A in other double-stranded viruses. The looser packing of L-A RNA allows for maneuverability in the crowded capsid interior, in which the genome (in both replication and transcription) must be translocated sequentially past the polymerase immobilized on the inner capsid wall.

The making and breaking of symmetry in virus capsid assembly: glimpses of capsid biology from cryoelectron microscopy.

Virus capsids constitute a diverse and versatile family of protein-bound containers and compartments ranging in diameter from approximately 200 A (mass approximately 1 MDa) to >1500 A (mass>250 MDa). Cryoelectron microscopy of capsids, now attaining resolutions down to 10 A, is disclosing novel structural motifs, assembly mechanisms, and the precise locations of major epitopes. Capsids are essentially symmetric structures, and icosahedral surface lattices have proved to be widespread. However, many capsid proteins exhibit a remarkable propensity for symmetry breaking, whereby chemically identical subunits in distinct lattice sites have markedly different structures and packing relationships. Temporal differences in the conformation of a given subunit are also manifested in the large-scale conformational changes that accompany capsid maturation. Larger and more complex capsids, such as DNA bacteriophages and herpes simplex virus, are formed not by simple self-assembly, but under the control of tightly regulated programs that may include the involvement of viral scaffolding proteins and cellular chaperonins, maturational proteolysis, and conformational changes on an epic scale. In addition to its significance for virology, capsid-related research has implications for biology in general, relating to the still largely obscure assembly processes of macromolecular complexes that perform many important cellular functions.

Differential domain accessibility to monoclonal antibodies in three different morphological assemblies built up by the S-layer protein of Thermus thermophilus HB8.

A collection of 27 monoclonal antibodies (MAbs) against the S-layer protein (P100) of Thermus thermophilus HB8 has been obtained. They have been classified according to their ability to recognize S-layer regions expressed in E. coli from plasmids containing different fragments of its coding gene, slpA. The accessibility of the binding sites in hexagonal, trigonal, or tetragonal assemblies of P100 was analyzed by enzyme-linked immunosorbent assays with six of these MAbs and their respective Fab fragments. When packed hexagonally as the native S-layer (S1 assemblies), only a small region located near the amino terminus of the P1OO was accessible. However, when P1OO was assembled into trigonal (pS2 assemblies) or tetragonal (S2 assemblies) arrays, most of the protein domains analyzed were easily detected, thus suggesting that P1OO is assembled in S2 and pS2 in a similar way and that these two arrangements are quite different from the S1 assembly. Relationships between accessibility and sequence predictions are discussed.

Horizontal transference of S-layer genes within Thermus thermophilus.

The S-layers of Thermus thermophilus HB27 and T. thermophilus HB8 are composed of protein units of 95 kDa (P95) and 100 kDa (P100), respectively. We have selected S-layer deletion mutants from both strains by complete replacement of the slpA gene. Mutants of the two strains showed similar defects in growth and morphology and overproduced an external cell envelope inside of which cells remained after division. However, the nature of this external layer is strain specific, being easily stained and regular in the HB8 delta slpA derivative and amorphous and poorly stained in the HB27 delta slpA strain. The addition of chromosomic DNA from T. thermophilus HB8 to growing cultures of T. thermophilus HB27 delta slpA led to the selection of a new strain, HB27C8, which expressed a functional S-layer composed of the P100 protein. Conversely, the addition of chromosomic DNA from T. thermophilus HB27 to growing cultures of T. thermophilus HB8 delta slpA allowed the isolation of strain HB8C27, which expressed a functional S-layer composed of the P95 protein. The driving force which selected the transference of the S-layer genes in these experiments was the difference in growth rates, one of the main factors leading to selection in natural environments.

Fungal virus capsids, cytoplasmic compartments for the replication of double-stranded RNA, formed as icosahedral shells of asymmetric Gag dimers.

The primary functions of most virus capsids are to protect the viral genome in the extra-cellular milieu and deliver it to the host. In contrast, the capsids of fungal viruses, like the cores of all other known double stranded RNA viruses, are not involved in host recognition but do shield their genomes, and they also carry out transcription and replication. Nascent (+) strands are extruded from transcribing virions. The capsids of the yeast virus L-A are composed of Gag (capsid protein; 76 kDa), with a few molecules of Gag-Pol (170 kDa). Analysis of these 420 A diameter shells and those of the fungal P4 virus by cryo-electron microscopy and image reconstruction shows that they share the same novel icosahedral structure. Both capsids consist of 60 equivalent Gag dimers, whose two subunits occupy non-equivalent bonding environments. Stoichiometry data on other double-stranded RNA viruses indicate that the 120-subunit structure is widespread, implying that this molecular architecture has features that are particularly favorable to the design of a capsid that is also a biosynthetic compartment.

Three-dimensional structure of different aggregates built up by the S-layer protein of Thermus thermophilus.

The 100-kDA S-layer protein from Thermus thermophilus HB8 is able to form three kinds of crystalline aggregates with different morphologies and symmetries when extracted from crude membranes using slightly different extractive procedures. Interestingly, only the structure showing P6 symmetry represents the native S-layer (called S1), while the others show a very different morphology. In this paper, the three-dimensional structure of each of these crystals revealing their topographic features at 2-3 nm resolution has been analyzed by electron microscopy and image processing. The S1 crystals contain an hexagonal center, probably build up by six monomers, where most of the protein mass is concentrated. These P6 centers account for the width of the native S-layer, being the connective domains of the subunits (two per subunit) located at the outermost part of the structure. Such connections radiating from different P6 centers are mediated through centers with P3 symmetry. The other two crystals are also consistent with a lattice based on trimeric subunits probably related to those found in the connections between P6 centers of S1. The most conspicuous feature of these two latter forms is the presence of trimers of channels that traverse the crystal in the direction perpendicular to the plane of the membrane. Their distinct morphology, quite different from other S-layer assemblies, shows a surprising adaptive potential of this protein, and suggests interesting evolutive relationships to other membrane proteins.

S-layer protein from Thermus thermophilus HB8 assembles into porin-like structures.

The cells of the extreme thermophile Thermus thermophilus are surrounded by a regular layer (S-layer) built up by a protein with an apparent molecular mass of 100 kDa (P100). From purified membrane fractions, three different class of two-dimensional crystals can be obtained by following alternative extractive procedures. One of these crystals, with p6 symmetry, clearly represents the native S-layer detected by freeze etching on whole cells, while the other two, showing p2 and p3 symmetries respectively, closely resemble aggregates of bacterial porins. We demonstrate here by limited proteolysis and Western blotting the surprising fact that the protein component of the three crystals is the P100 protein. Our biochemical data also show how this protein forms Ca(2+)-stabilized trimers in each crystal, which support the structural analysis that points to p3 units as the common structural block in all of them, and again resembles the situation found in bacterial porins.

Insertional mutagenesis in the extreme thermophilic eubacteria Thermus thermophilus HB8.

The transcription and translation signals of the S-layer gene (slpA) from Thermus thermophilus HB8 have been used to express a thermostable kanamycin adenyl transferase gene in this organism. The chimaeric resistance gene was inserted in vitro into slpA to produce different inactive forms of the gene, which were used to transform T. thermophilus HB8. After 48 hours of incubation at 70 degrees C, only two constructions that contained the kat gene flanked by Thermus sequences from both sides of slpA were able to produce protein layer (P100)-defective mutants. The mutants obtained with both constructions showed identical protein patterns, in which a major 50 kDa protein and two other minor proteins were tentatively identified as P100 fragments, expressed from the extreme 5' end of slpA. They also exhibited important phenotypic defects, such as slow growth in liquid broth, a tendency to aggregate as 'rotund bodies', a twisted filamentous shape, and an extreme sensitivity to lysozyme, suggesting protective and shaping roles for the S-layer in T. thermophilus HB8. These results also demonstrate for the first time the feasibility of using selective antibiotic-resistance markers in extreme thermophiles.