Engineering the HK97 virus-like particle as a nanoplatform for biotechnology applications.

The research described here looks at the development of virus-like particles (VLPs) derived from bacteriophage HK97 as versatile scaffolds for bionanomaterials construction. Based on molecular models, the Prohead I HK97 VLP was engineered to allow attachment of small molecules to the interior by introducing a reactive cysteine into the genetic sequence of the HK97 GP5 protein that self assembles to form the VLP structure. In addition, methods for entrapping large protein macromolecules were evaluated and found to produce high encapsulation numbers of green fluorescent proteins (GFP) in the internal space of the HK97 VLP. A method for modular modification of the external surface was engineered by constructing a plasmid allowing the addition of peptide sequences to the C-terminus of the GP5 protein, which was validated by appending the sortase recognition peptide sequence, LPETG, to the C-terminus of GP5 and showing the attachment of a polyglycine-GFP to the HK97 VLP through sortase mediated ligation. To demonstrate the potential for advanced applications, an HK97 VLP covalently labeled on the interior surface with fluorescein and containing an externally displayed integrin binding peptide sequence (RGD) was evaluated and found to be preferentially localized at C2C12 cells relative to the HK97 VLP lacking the RGD peptide. Together, these results support the potential of the HK97 VLP as a versatile nanoparticle platform that can be modified internally and externally in a modular fashion for the purpose of programming the VLP for desired applications.

Engineering soluble artificial epidermal growth factor receptor mimics capable of spontaneous in vitro dimerization.

Epidermal growth factor receptor (EGFR) is a clinically validated target for a multitude of human cancers. The receptor is activated upon ligand binding through a critical dimerization step. Dimerization can be replicated in vitro by locally concentrating the receptor kinase domains on the surface of lipid-based vesicles. In this study we investigated the use of coiled coils to induce spontaneous receptor kinase domain dimerization in vitro to form non-membrane-bound artificial receptor mimics in solution. Two engineered forms of EGFR kinase domain fused to coiled coil complementary peptides were designed to self-associate upon mixing. Two fusion protein species (P3-EGFR and P4-EGFR) independently showed the same activity and polymerization profile known to exist with EGFR kinase domains. Upon mixing the two species, coiled coil heterodimers were formed that induced EGFR association to form dimers of the kinase domains. This was accompanied by 11.5-fold increase in the phosphorylation rate indicative of kinase domain activation equivalent to the levels achieved using vesicle localization and mimicking in vivo ligand-induced activation. This study presents a soluble tyrosine kinase receptor mimic capable of spontaneous in vitro activation that can facilitate functional and drug discovery studies for this clinically important receptor class.

Sortase-Mediated Ligation as a Modular Approach for the Covalent Attachment of Proteins to the Exterior of the Bacteriophage P22 Virus-like Particle.

Virus-like particles are unique platforms well suited for the construction of nanomaterials with broad-range applications. The research presented here describes the development of a modular approach for the covalent attachment of protein domains to the exterior of the versatile bacteriophage P22 virus-like particle (VLP) via a sortase-mediated ligation strategy. The bacteriophage P22 coat protein was genetically engineered to incorporate an LPETG amino acid sequence on the C-terminus, providing the peptide recognition sequence utilized by the sortase enzyme to catalyze peptide bond formation between the LPETG-tagged protein and a protein containing a polyglycine sequence on the N-terminus. Here we evaluate attachment of green fluorescent protein (GFP) and the head domain of the influenza hemagglutinin (HA) protein by genetically producing polyglycine tagged proteins. Attachment of both proteins to the exterior of the P22 VLP was found to be highly efficient as judged by SDS-PAGE densitometry. These results enlarge the tool kit for modifying the P22 VLP system and provide new insights for other VLPs that have an externally displayed C-terminus that can use the described strategy for the modular modification of their external surface for various applications.

Design of a VLP-nanovehicle for CYP450 enzymatic activity delivery.

BACKGROUND: The intracellular delivery of enzymes for therapeutic use has a promising future for the treatment of several diseases such as genetic disorders and cancer. Virus-like particles offer an interesting platform for enzymatic delivery to targeted cells because of their great cargo capacity and the enhancement of the biocatalyst stability towards several factors important in the practical application of these nanoparticles. RESULTS: We have designed a nano-bioreactor based on the encapsulation of a cytochrome P450 (CYP) inside the capsid derived from the bacteriophage P22. An enhanced peroxigenase, CYPBM3, was selected as a model enzyme because of its potential in enzyme prodrug therapy. A total of 109 enzymes per capsid were encapsulated with a 70 % retention of activity for cytochromes with the correct incorporation of the heme cofactor. Upon encapsulation, the stability of the enzyme towards protease degradation and acidic pH was increased. Cytochrome P450 activity was delivered into Human cervix carcinoma cells via transfecting P22-CYP nanoparticles with lipofectamine. CONCLUSION: This work provides a clear demonstration of the potential of biocatalytic virus-like particles as medical relevant enzymatic delivery vehicles for clinical applications.

Characterization of a highly flexible self-assembling protein system designed to form nanocages.

The design of proteins that self-assemble into well-defined, higher order structures is an important goal that has potential applications in synthetic biology, materials science, and medicine. We previously designed a two-component protein system, designated A-(+) and A-(-), in which self-assembly is mediated by complementary electrostatic interactions between two coiled-coil sequences appended to the C-terminus of a homotrimeric enzyme with C3 symmetry. The coiled-coil sequences are attached through a short, flexible spacer sequence providing the system with a high degree of conformational flexibility. Thus, the primary constraint guiding which structures the system may assemble into is the symmetry of the protein building block. We have now characterized the properties of the self-assembling system as a whole using native gel electrophoresis and analytical ultracentrifugation (AUC) and the properties of individual assemblies using cryo-electron microscopy (EM). We show that upon mixing, A-(+) and A-(-) form only six different complexes in significant concentrations. The three predominant complexes have hydrodynamic properties consistent with the formation of heterodimeric, tetrahedral, and octahedral protein cages. Cryo-EM of size-fractionated material shows that A-(+) and A-(-) form spherical particles with diameters appropriate for tetrahedral or octahedral protein cages. The particles varied in diameter in an almost continuous manner suggesting that their structures are extremely flexible.

Adenosyl radical: reagent and catalyst in enzyme reactions.

Adenosine is undoubtedly an ancient biological molecule that is a component of many enzyme cofactors: ATP, FADH, NAD(P)H, and coenzyme A, to name but a few, and, of course, of RNA. Here we present an overview of the role of adenosine in its most reactive form: as an organic radical formed either by homolytic cleavage of adenosylcobalamin (coenzyme B(12), AdoCbl) or by single-electron reduction of S-adenosylmethionine (AdoMet) complexed to an iron-sulfur cluster. Although many of the enzymes we discuss are newly discovered, adenosine's role as a radical cofactor most likely arose very early in evolution, before the advent of photosynthesis and the production of molecular oxygen, which rapidly inactivates many radical enzymes. AdoCbl-dependent enzymes appear to be confined to a rather narrow repertoire of rearrangement reactions involving 1,2-hydrogen atom migrations; nevertheless, mechanistic insights gained from studying these enzymes have proved extremely valuable in understanding how enzymes generate and control highly reactive free radical intermediates. In contrast, there has been a recent explosion in the number of radical-AdoMet enzymes discovered that catalyze a remarkably wide range of chemically challenging reactions; here there is much still to learn about their mechanisms. Although all the radical-AdoMet enzymes so far characterized come from anaerobically growing microbes and are very oxygen sensitive, there is tantalizing evidence that some of these enzymes might be active in aerobic organisms including humans.

Subunit structure of benzylsuccinate synthase.

Benzylsuccinate synthase is a member of the glycyl radical family of enzymes. It catalyzes the addition of toluene to fumarate to form benzylsuccinate as the first step in the anaerobic pathway of toluene fermentation. The enzyme comprises three subunits, alpha, beta, and gamma, that in Thauera aromatica strain T1 are encoded by the tutD, tutG, and tutF genes, respectively. The large alpha-subunit contains the essential glycine and cysteine residues that are conserved in all glycyl radical enzymes. However, the function of the small beta- and gamma-subunits has remained unclear. We have overexpressed all three subunits of benzylsuccinate synthase in Escherichia coli, both individually and in combination. Coexpression of the gamma-subunit (but not the beta-subunit) is essential for efficient expression of the alpha-subunit. The benzylsuccinate synthase complex lacking the glycyl radical could be purified as an alpha(2)beta(2)gamma(2) hexamer by nickel affinity chromatography through a "His(6)" affinity tag engineered onto the C-terminus of the alpha-subunit. Unexpectedly, BSS was found to contain two iron-sulfur clusters, one associated with the beta-subunit and the other with the gamma-subunit that appear to be necessary for the structural integrity of the complex. The spectroscopic properties of these clusters suggest that they are most likely [4Fe-4S] clusters. Removal of iron with chelating agents results in dissociation of the complex; similarly, a mutant gamma-subunit lacking the [4Fe-4S] cluster is unable to stabilize the alpha-subunit when the proteins are coexpressed.