Phage capsid nanoparticles with defined ligand arrangement block influenza virus entry

Multivalent interactions at biological interfaces occur frequently in nature and mediate recognition and interactions in essential physiological processes such as cell-to-cell adhesion. Multivalency is also a key principle that allows tight binding between pathogens and host cells during the initial stages of infection. One promising approach to prevent infection is the design of synthetic or semisynthetic multivalent binders that interfere with pathogen adhesion^1-4. Here, we present a multivalent binder that is based on a spatially defined arrangement of ligands for the viral spike protein haemagglutinin of the influenza A virus. Complementary experimental and theoretical approaches demonstrate that bacteriophage capsids, which carry host cell haemagglutinin ligands in an arrangement matching the geometry of binding sites of the spike protein, can bind to viruses in a defined multivalent mode. These capsids cover the entire virus envelope, thus preventing its binding to the host cell as visualized by cryo-electron tomography. As a consequence, virus infection can be inhibited in vitro, ex vivo and in vivo. Such highly functionalized capsids present an alternative to strategies that target virus entry by spike-inhibiting antibodies⁵ and peptides⁶ or that address late steps of the viral replication cycle⁷.

Head-to-Head Comparison of Soluble vs. Qβ VLP Circumsporozoite Protein Vaccines Reveals Selective Enhancement of NANP Repeat Responses

Circumsporozoite protein (CSP) of Plasmodium falciparum is a promising malaria vaccine target. RTS,S, the most advanced malaria vaccine candidate consists of the central NANP repeat and carboxy-terminal region of CSP displayed on a hepatitis B virus-like particle (VLP). To build upon the success of RTS,S, we produced a near full-length Plasmodium falciparum CSP that also includes the conserved amino-terminal region of CSP. We recently showed that this soluble CSP, combined with a synthetic Toll-like-receptor-4 (TLR4) agonist in stable oil-in-water emulsion (GLA/SE), induces a potent and protective immune response in mice against transgenic parasite challenge. Here we have investigated whether the immunogenicity of soluble CSP could be further augmented by presentation on a VLP. Bacteriophage Qβ VLPs can be readily produced in E.coli, they have a diameter of 25 nm and contain packaged E. coli RNA which serves as a built in adjuvant through the activation of TLR7/8. CSP was chemically conjugated to Qβ and the CSP-Qβ vaccine immunogenicity and efficacy were compared to adjuvanted soluble CSP in the C57Bl/6 mouse model. When formulated with adjuvants lacking a TLR4 agonist (Alum, SE and Montanide) the Qβ-CSP induced higher anti-NANP repeat titers, higher levels of cytophilic IgG2b/c antibodies and a trend towards higher protection against transgenic parasite challenge as compared to soluble CSP formulated in the same adjuvant. The VLP and soluble CSP immunogenicity difference was most pronounced at low antigen dose, and within the CSP molecule, the titers against the NANP repeats were preferentially enhanced by Qβ presentation. While a TLR4 agonist enhanced the immunogenicity of soluble CSP to levels comparable to the VLP vaccine, the TLR4 agonist did not further improve the immunogenicity of the Qβ-CSP vaccine. The data presented here pave the way for further improvement in the Qβ conjugation chemistry and evaluation of both the Qβ-CSP and soluble CSP vaccines in the non-human primate model.

Inactivation of F-specific bacteriophages during flocculation with polyaluminum chloride - a mechanistic study

Bacteriophages are often used as surrogates for enteric viruses in spiking experiments to determine the efficiencies of virus removal of certain water treatment measures, like e.g. flocculation or filtration steps. Such spiking experiments with bacteriophages are indispensable if the natural virus concentrations in the raw water of water treatment plants are too low to allow the determination of elimination levels over several orders of magnitude. In order to obtain reliable results from such spiking tests, it is essential that bacteriophages behave comparable to viruses and remain stable during the experiments. To test this, the influence of flocculation parameters on the bacteriophages MS2, Qβ and phiX174 was examined. Notably, the F-specific phages MS2 and Qβ were found to be inactivated in flocculation processes with polyaluminum chloride (PACl). In contrast, other aluminum coagulants like AlCl3 or Al2(SO4)3 did not show a comparable effect on MS2 in this study. In experiments testing the influence of different PACl species on MS2 and Qβ inactivation during flocculation, it could be shown that cationic dissolved PACl species (Al13) interacted with the MS2 surface and hereby reduced the surviving phage fraction to c/c0 values below 1*10(-4) even at very low PACl concentrations of 7 μmol Al/L. Other inactivation mechanisms like the irreversible adsorption of phages to the floc structure or the damage of phage surfaces due to entrapment into the floc during coagulation and floc formation do not seem to contribute to the low surviving fraction found for both F-specific bacteriophages. Furthermore, no influence of phage agglomeration or pH drops during the flocculation process on phage inactivation could be observed. The somatic coliphage phiX174 in contrast did not show sensitivity to chemical stress and in accordance only slight interaction between Al13 and the phage surface was observed. Consequently, F-specific phages like MS2 should not be used as surrogate for viruses in flocculation experiments with PACl to determine the removal rates of viruses, as the results are influenced by a strong inactivation of the bacteriophages due to the experimental conditions.

Evolution and protein packaging of small-molecule RNA aptamers

A high-affinity RNA aptamer (K(d) = 50 nM) was efficiently identified by SELEX against a heteroaryldihydropyrimidine structure, chosen as a representative drug-like molecule with no cross reactivity with mammalian or bacterial cells. This aptamer, its weaker-binding variants, and a known aptamer against theophylline were each embedded in a longer RNA sequence that was encapsidated inside a virus-like particle by a convenient expression technique. These nucleoprotein particles were shown by backscattering interferometry to bind to the small-molecule ligands with affinities similar to those of the free (nonencapsidated) aptamers. The system therefore comprises a general approach to the production and sequestration of functional RNA molecules, characterized by a convenient label-free analytical technique.

RNA-directed packaging of enzymes within virus-like particles

Packaged molecular machines are available in large amounts using dual expression vectors that guide the preparation of Qβ virus-like particles encapsulating multiple copies of functional enzymes. Packaging is promoted by RNA aptamer sequences that bridge between the coat protein and a peptide tag fused to the desired cargo. Peptidase E and luciferase were thus encapsulated and shown to be catalytically active inside the particle. The encapsulated enzymes are less sensitive to inactivation by heating and surface adsorption than the corresponding free enzymes. This system represents a modular way to marry catalytic activity with robust scaffolding for the development of multifunctional materials.

Multivalent display and receptor-mediated endocytosis of transferrin on virus-like particles

The structurally regular and stable self-assembled capsids derived from viruses can be used as scaffolds for the display of multiple copies of cell- and tissue-targeting molecules and therapeutic agents in a convenient and well-defined manner. The human iron-transfer protein transferrin, a high affinity ligand for receptors upregulated in a variety of cancers, has been arrayed on the exterior surface of the protein capsid of bacteriophage Qbeta. Selective oxidation of the sialic acid residues on the glycan chains of transferrin was followed by introduction of a terminal alkyne functionality through an oxime linkage. Attachment of the protein to azide-functionalized Qbeta capsid particles in an orientation allowing access to the receptor binding site was accomplished by the Cu(I)-catalyzed azide-alkyne cycloaddition (CuAAC) click reaction. Transferrin conjugation to Qbeta particles allowed specific recognition by transferrin receptors and cellular internalization through clathrin-mediated endocytosis, as determined by fluorescence microscopy on cells expressing GFP-labeled clathrin light chains. By testing Qbeta particles bearing different numbers of transferrin molecules, it was demonstrated that cellular uptake was proportional to ligand density, but that internalization was inhibited by equivalent concentrations of free transferrin. These results suggest that cell targeting with transferrin can be improved by local concentration (avidity) effects.

Assembly of hybrid bacteriophage Qbeta virus-like particles

Bacteriophage Qbeta coat protein forms uniform virus-like particles when expressed recombinantly in a variety of organisms. We have inserted the IgG-binding Z domain at the carboxy terminus of the coat protein and coexpressed this chimeric subunit with native coat protein to create hybrid, IgG-binding virus-like particles. Extracellular osmolytes were found to have an effect on the efficiency of incorporation of fusion proteins into VLPs in Escherichia coli when a carbenicillin, but not a kanamycin, selection marker was used. The addition of sucrose to the growth medium decreased the incorporation efficiency; the osmoprotectant glycine betaine eliminated this effect. The decrease in efficiency was not observed when carbenicillin was omitted from the final expression culture. The addition of sodium chloride instead of sucrose gave rise to particles with a larger number of fusion proteins than the standard conditions. These results illustrate that cellular conditions should be taken into account even in apparently simple systems when natural or engineered protein nanoparticles are made.

Unnatural amino acid incorporation into virus-like particles

Virus-like particles composed of hepatitis B virus (HBV) or bacteriophage Qbeta capsid proteins have been labeled with azide- or alkyne-containing unnatural amino acids by expression in a methionine auxotrophic strain of E. coli. The substitution does not affect the ability of the particles to self-assemble into icosahedral structures indistinguishable from native forms. The azide and alkyne groups were addressed by Cu(I)-catalyzed [3 + 2] cycloaddition: HBV particles were decomposed by the formation of more than 120 triazole linkages per capsid in a location-dependent manner, whereas Qbeta suffered no such instability. The marriage of these well-known techniques of sense-codon reassignment and bioorthogonal chemical coupling provides the capability to construct polyvalent particles displaying a wide variety of functional groups with near-perfect control of spacing.

Assembly of bacteriophage Qbeta virus-like particles in yeast Saccharomyces cerevisiae and Pichia pastoris

Recombinant bacteriophage Qbeta coat protein (CP), which has been proposed as a promising carrier of foreign epitopes via their incorporation either by gene engineering techniques or by chemical coupling, efficiently self-assembles into virus-like particles (VLPs) when expressed in Escherichia coli. Here, we demonstrate expression and self-assembly of Qbeta CP in yeast Saccharomyces cerevisiae and Pichia pastoris. Production reached 3-4 mg/1g of wet cells for S. cerevisiae and 4-6 mg for P. pastoris, which was about 15-20% and 20-30% of the E. coli expression level, respectively. Qbeta VLPs were easily purified by size-exclusion chromatography in both cases and contained nucleic acid, shown by native agarose gel electrophoresis. The obtained particles were highly immunogenic in mice and the resulting sera recognized both E. coli- and yeast-derived Qbeta VLPs equally well.

The influence of ionic strength on the interaction of viruses with charged surfaces under environmental conditions

The influence of ionic strength on the electrostatic interaction of viruses with environmentally relevant surfaces was determined for three viruses, MS2, Q beta, and Norwalk. The virus is modeled as a particle comprised of ionizable amino acid residues in a shell surrounding a spherical RNA core of negative charge, these charges being compensated for by a Coulomb screening due to intercalated ions. A second model of the virus involving surface charges only is included for comparison. Surface potential calculations for each of the viruses show excellent agreement with electrophoretic mobility and zeta potential measurements as a function of pH. The environmental surface is modeled as a homogeneous plane held at constant potential with and without a finite region (patch) of opposite potential. The results indicate that the electrostatic interaction between the virus and the oppositely charged patch is significantly influenced by the conditions of ionic strength, pH and size of the patch. Specifically, at pH 7, the Norwalk virus interacts more strongly with the patch than MS2 (approximately 51 vs approximately 9kT) but at pH 5, the Norwalk-surface interaction is negligible while that of MS2 is approximately 5.9kT. The resulting ramifications for the use of MS2 as a surrogate for Norwalk are discussed.

Rapid Response of Marginal Zone B Cells to Viral Particles

Marginal zone (MZ) B cells are thought to be responsible for the first wave of Abs against bacterial Ags. In this study, we assessed the in vivo response of MZ B cells in mice immunized with viral particles derived from the RNA phage Qbeta. We found that both follicular (FO) and MZ B cells responded to immunization with viral particles. MZ B cells responded with slightly faster kinetics, but numerically, FO B cells dominated the response. B1 B cells responded similarly to MZ B cells. Both MZ and FO B cells underwent isotype switching, with MZ B cells again exhibiting faster kinetics. In fact, almost all Qbeta-specific MZ B cells expressed surface IgG by day 5. Histological analysis demonstrated that a population of activated B cells remain associated with the MZ, probably due to the elevated integrin levels expressed by these cells. Thus, both MZ and FO B cells respond with rapid proliferation to viral infection and both populations undergo isotype switching, but MZ B cells remain in the MZ and may be responsible for local Ab production, opsonizing pathogens entering the spleen.

A protein antibiotic in the phage Qbeta virion: diversity in lysis targets

A(2), a capsid protein of RNA phage Qbeta, is also responsible for host lysis. A(2) blocked synthesis of murein precursors in vivo by inhibiting MurA, the catalyst of the committed step of murein biosynthesis. An A(2)-resistance mutation mapped to an exposed surface near the substrate-binding cleft of MurA. Moreover, purified Qbeta virions inhibited wild-type MurA, but not the mutant MurA, in vitro. Thus, the two small phages characterized for their lysis strategy, Qbeta and the small DNA phage phiX174, effect host lysis by targeting different enzymes in the multistep, universally conserved pathway of cell wall biosynthesis.

CCA initiation boxes without unique promoter elements support in vitro transcription by three viral RNA-dependent RNA polymerases

It has previously been observed that the only specific requirement for transcriptional initiation on viral RNA in vitro by the RNA-dependent RNA polymerase (RdRp) of turnip yellow mosaic virus is the CCA at the 3' end of the genome. We now compare the abilities of this RdRp, turnip crinkle virus RdRp, and Qbeta replicase, an enzyme capable of supporting the complete viral replication cycle in vitro, to transcribe RNA templates containing multiple CCA boxes but lacking specific viral sequences. Each enzyme is able to initiate transcription from several CCA boxes within these RNAs, and no special reaction conditions are required for these activities. The transcriptional yields produced from templates comprised of multiple CCA or CCCA repeats relative to templates derived from native viral RNA sequences vary between 2:1 and 0.1:1 for the different RdRps. Control of initiation by such redundant sequences presents a challenge to the specificity of viral transcription and replication. We identify 3'-preferential initiation and sensitivity to structural presentation as two specificity mechanisms that can limit initiation among potential CCA initiation sites. These two specificity mechanisms are used to different degrees by the three RdRps. The finding that three viral RdRps representing two of the three supergroups within the positive-strand RNA viral RdRp phylogeny support substantial transcription in the absence of unique promoters suggests that this phenomenon may be common among positive-strand viruses. A framework is presented arguing that replication of viral RNA in the absence of unique promoter elements is feasible.

Translational activation in coliphage Qbeta: on a polycistronic messenger RNA, repression of one gene can activate translation of another

We present evidence for translational activation of the Qbeta coliphage maturation cistron, mediated by the presence of Qbeta replicase. This activation does not require RNA replication, translation of a second gene, or any direct protein-RNA binding at the maturation gene initiation site. Our data support a model in which the Qbeta maturation gene remains translationally "off" by two means: (1) the thermodynamic stability of an RNA structure that greatly discourages, but does not eliminate, ribosome access at the maturation start site; and (2) the presence of the stronger, proximal coat gene ribosome binding site. Moreover, maturation gene expression is switched "on" when ribosome entry at the coat initiation site, present on the same polycistronic RNA molecule, is repressed by Qbeta replicase, thereby allowing ribosomes to compete for the weaker, upstream maturation start site.

Secondary structure model for the first three domains of Q beta RNA. Control of A-protein synthesis

We present a secondary structure model for the first 860 nucleotides of Q beta RNA. The model is supported by phylogenetic comparison, nuclease S1 structure probing and computer prediction using energy minimization and a Monte Carlo approach. To provide the necessary data for the comparative analysis we have sequenced the single-stranded RNA coliphages MX1, M11 and NL95. Together with the known sequences of Q beta and SP, this yields five sequences with sufficient sequence diversity to be useful for the analysis. The part of the Q beta genome examined contains the 60 nucleotide 5' untranslated region and the first 800 nucleotide of the maturation protein gene. The RNA adopts a highly ordered structure in which all hairpins are held in place by a network of long-distance interactions, which form three-way and four-way junctions. Only the 5'-terminal hairpin is unrestrained, while connected by a few single-stranded nucleotides to the body of the RNA. The start region of the A-protein gene, which is part of the network of long-distance interactions, is base-paired to three non-contiguous downstream sequences. As a result, translation is expected to be progressively quenched when the length of the nascent chains increases. This feature explains the previous observation that A-protein synthesis on Q beta RNA can start only on short nascent strands. Translational control of the A protein in the distantly related phage MS2 was recently shown to be controlled by the kinetics of RNA folding. This basic difference and its possible biological purpose can be explained by the different RNA folding pathways in Q beta and MS2. Interestingly, due to the presence of G-U pairs, structure prediction for the minus strand differs in some aspects from that for the plus strand. More specifically, there is a minus-strand specific, long-distance interaction bordering the minus-strand equivalent of the 5'-terminal hairpin. This interaction extends at the expense of the lower part of the terminal helix, thereby exposing the terminal C residues at which replication starts. This long-distance interaction, which was recently shown to be required for minus-strand replication, is strongly supported by our comparative data.

A complete plasmid-based complementation system for RNA coliphage Q beta: three proteins of bacteriophages Q beta (group III) and SP (group IV) can be interchanged

Our laboratory has established a bacteriophage Q beta cDNA-containing plasmid system in which virtually all coding defects present within the 4217 nucleotide Q beta genome can be complemented in trans. In this system, Q beta minus strand RNAs are constitutively transcribed from plasmid cDNA by Escherichia coli RNA polymerase. Replication of these minus strands results in the synthesis of Q beta plus RNA, thereby triggering an infectious cycle in which Q beta phase particles are generated. Genetically engineered Q beta genome mutations that result in defective viral proteins can be complemented in trans by the products of one or more Q beta helper plasmids that express either: (1) Q beta maturation protein, which can complement defects in the Q beta maturation cistron (nucleotides 61 to 1320); (2) Q beta readthrough protein, which can complement defects in the readthrough cistron (nucleotides 1344 to 2330); or (3) Q beta replicase, which can complement defects in the replicase cistron (nucleotides 2352 to 4118). Each plasmid component of this system contains a unique origin of replication and carries a different antibiotic gene, thereby enabling all combinations of these plasmids to coexist in the same host. We have further developed a second series of helper plasmids that generate the corresponding viral proteins of the related group IV RNA phage SP. Each of these SP helper proteins can complement respective defects within the Q beta genome with efficiencies similar to those observed for the Q beta helper proteins. It is now possible to supply functional Q beta or SP proteins in trans to examine Q beta genomes that contain protein coding defects for their ability to synthesize Q beta proteins, replicate Q beta RNA, assemble virions, and/or lyse the host cell.

Evolution of host cell RNA into efficient template RNA by Q beta replicase: the origin of RNA in untemplated reactions

Q beta replicase can replicate a single molecule of certain species of RNA to 10(14) copies in minutes. This replication ability has been used for in vitro studies of molecular evolution and is currently being utilized as a method of amplifying RNAs that contain probe sequences. It has been observed that Q beta replicase can produce replicatable RNA even in the absence of exogenously added template RNA. The origin of this RNA has been ascribed either to contamination with replicatable RNA or to an ability of Q beta replicase to synthesize RNA de novo from the nucleotides present in the reaction. Technologies that employ Q beta replicase require a thorough understanding of the conditions that lead to this so-called spontaneous RNA production. We have created an expression system and purification method with which we produce gram quantities of highly purified Q beta replicase, and we have identified reaction conditions that prevent the amplification of RNA in assays that do not contain added RNA. However, when these reaction conditions are relaxed, spontaneous RNA replication is seen in up to 100% of the assays. To understand the origin of this RNA, we have cloned several spontaneously produced RNAs. Sequence analysis of one of these RNAs shows that it arose by the evolution of Escherichia coli tRNA into a replicatable template and not by de novo synthesis from nucleoside triphosphates in the reaction.

On producing more complexity than entropy in replication

RNA replication in the bacteriophage Q beta system can, in principle, transmit sequence complexity at a higher rate than it increases entropy. Expanding the variety of nucleotides, through novel base-pair interactions, would move the threshold at which synthesis produces more complexity than entropy away from near equilibrium while accelerating the system approach to equilibrium. A decrease in sequence complexity during polymerization, leading to a many-to-one monomer correspondence with template, cannot be reversed, owing to symmetry restrictions. In terms of the kinetic mechanism, uncertainty associated with the the path of depolymerization yields a path entropy which selectively prolongs the reverse reaction. Together with an elevation in thermodynamic entropy, therefore, there are two possible sources of irreversibility in a physical process. Some implications of kinetic irreversibility are considered in relation to the second law of thermodynamics and to the processing and translation of mRNA.

Quantitative analysis of mutation and selection in self-replicating RNA

Mutation and selection as principles of Darwinian evolution have contributed a wealth to qualitative insight and understanding of complex biological organizations. However, for quantitative measurements of Darwinian evolution, only model systems are sufficiently simple to allow calculation of values for the relevant evolution parameters. The model system used for our study comprises short-chained RNA species whose self-replication is catalyzed by Q beta replicase. In this system, phenotypic expression of a genotype is reduced to its efficiency in directing its own synthesis. The mechanism of single-stranded RNA reproduction is well understood: RNA synthesis profiles can be described by compact equations. The selection behaviour of competing RNA species can be precisely predicted, using these equations, from kinetic parameters of the species: at low concentrations, RNA species are selected for overall growth rate (fecundity), at higher concentrations, for rapid binding of replicase (selection for competition), and at still higher concentrations, for minimizing losses caused by formation of inactive double strands. Finally, an ecosystem may be established where the different species coexist, their relative concentrations being functions of their kinetic parameters. The analysis of competition and selection can be extended to mutants of a species. Experimental conditions can be found where quantitative measurement of mutation rates and selective values of mutants is possible. The interplay of mutation and selection results in establishing a quasispecies distribution where mutants are represented according to their rates of mutational formation and their selective values. Replicating RNA clones, when amplified, rapidly build up quasispecies distributions containing pronounced "hot spots", produced predominantly by error propagation of nearly neutral mutants. The primitive model system shows the same complex Darwinian behaviour as observed in evolution of biological systems. In the absence of extraneously added template, Q beta replicase synthesizes after long lag times self-replicating RNA de novo. In a first step, nucleoside triphosphates are condensed randomly; self-replicating templates produced by chance are amplified and optimized.