Martin G. Nussbaumer scite author profile

Vesicles assembled from amphiphilic block copolymers represent promising nanomaterials for applications that include drug delivery and surface functionalization. One essential requirement to guide such polymersomes to a desired site in vivo is conjugation of active, targeting ligands to the surface of preformed self-assemblies. Such conjugation chemistry must fulfill criteria of efficiency and selectivity, stability of the resulting bond, and biocompatibility. We have here developed a new system that achieves these criteria by simple conjugation of 4-formylbenzoate (4FB) functionalized polymersomes with 6-hydrazinonicotinate acetone hydrazone (HyNic) functionalized antibodies in aqueous buffer. The number of available amino groups on the surface of polymersomes composed of poly(dimethylsiloxane)-block-poly(2-methyloxazoline) diblock copolymers was investigated by reacting hydrophilic succinimidyl-activated fluorescent dye with polymersomes and evaluating the resulting emission intensity. To prove attachment of biomolecules to polymersomes, HyNic functionalized enhanced yellow fluorescent protein (eYFP) was attached to 4FB functionalized polymersomes, resulting in an average number of 5 eYFP molecules per polymersome. Two different polymersome-antibody conjugates were produced using either antibiotin IgG or trastuzumab. They showed specific targeting toward biotin-patterned surfaces and breast cancer cells. Overall, the polymersome-ligand platform appears promising for therapeutic and diagnostic use.

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Protein cages and synthetic polymers: a fruitful symbiosis for drug delivery applications, bionanotechnology and materials science

Rother

et al. 2016

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Protein cages are hollow protein nanoparticles, such as viral capsids, virus-like particles, ferritin, heat-shock proteins and chaperonins. They have well-defined capsule-like structures with a monodisperse size. Their protein subunits can be modified by genetic engineering at predetermined positions, allowing for example site-selective introduction of attachment points for functional groups, catalysts or targeting ligands on their outer surface, in their interior and between subunits. Therefore, protein cages have been extensively explored as functional entities in bionanotechnology, as drug-delivery or gene-delivery vehicles, as nanoreactors or as templates for the synthesis of organic and inorganic nanomaterials. The scope of functionalities and applications of protein cages can be significantly broadened if they are combined with synthetic polymers on their surface or within their interior. For example, PEGylation reduces the immunogenicity of protein cage-based delivery systems and active targeting ligands can be attached via polymer chains to favour their accumulation in diseased tissue. Polymers within protein cages offer the possibility of increasing the loading density of drug molecules, nucleic acids, magnetic resonance imaging contrast agents or catalysts. Moreover, the interaction of protein cages and polymers can be used to modulate the size and shape of some viral capsids to generate structures that do not occur with native viruses. Another possibility is to use the interior of polymer cages as a confined reaction space for polymerization reactions such as atom transfer radical polymerization or rhodium-catalysed polymerization of phenylacetylene. The protein nanoreactors facilitate a higher degree of control over polymer synthesis. This review will summarize the hybrid structures that have been synthesized by polymerizing from protein cage-bound initiators, by conjugating polymers to protein cages, by embedding protein cages into bulk polymeric materials, by forming two- and three-dimensional crystals of protein cages and dendrimers, by adsorbing proteins to the surface of materials, by layer-by-layer deposition of proteins and polyelectrolytes and by encapsulating polymers into protein cages. The application of these hybrid materials in the biomedical context or as tools and building blocks for bionanotechnology, biosensing, memory devices and the synthesis of materials will be highlighted. The review aims to showcase recent developments in this field and to suggest possible future directions and opportunities for the symbiosis of protein cages and polymers.

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Engineered catalytic biofilms: Site‐specific enzyme immobilization onto E. coli curli nanofibers

Botyanszki

Tay

Nguyen

et al. 2015

Biotech & Bioengineering

124

116

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23Biocatalytic transformations generally rely on purified enzymes or whole cells to perform 24 complex transformations that are used on industrial scales for chemical, drug, and biofuel 25 synthesis, pesticide decontamination and water purification. However, both of these systems 26 have inherent disadvantages related to the costs associated with enzyme purification, the long-27 term stability of immobilized enzymes, catalyst recovery and compatibility with harsh reaction 28 conditions. We developed a novel strategy for producing rationally designed biocatalytic 29 surfaces based on Biofilm Integrated Nanofiber Display (BIND), which exploits the curli system 30 of E. coli to create a functional nanofiber network capable of covalent immobilization of 31 enzymes. This approach is attractive because it is scalable, represents a modular strategy for site-32 specific enzyme immobilization, and has the potential to stabilize enzymes under denaturing 33 environmental conditions. We site-specifically immobilized a recombinant α-amylase, fused to 34 the SpyCatcher attachment domain, onto E. coli curli fibers displaying complementary SpyTag 35 capture domains. We characterized the effectiveness of this immobilization technique on the 36 biofilms and tested the stability of immobilized α-amylase in unfavorable conditions. This 37 enzyme-modified biofilm maintained its activity when exposed to a wide range of pH and 38 organic solvent conditions. In contrast to other biofilm-based catalysts, which rely on cellular 39 metabolism to remain active, the modified curli-based biofilm remained active even after cell 40 death due to organic solvent exposure. This work lays the foundation for a new and versatile 41 method of using the extracellular polymeric matrix of E. coli for creating novel biocatalytic 42 surfaces. 43 44 3

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Fluorescent Protein Senses and Reports Mechanical Damage in Glass‐Fiber‐Reinforced Polymer Composites

et al. 2013

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A Chaperonin as Protein Nanoreactor for Atom‐Transfer Radical Polymerization

et al. 2013

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The group II chaperonin thermosome (THS) from the archaea Thermoplasma acidophilum is reported as nanoreactor for atom-transfer radical polymerization (ATRP). A copper catalyst was entrapped into the THS to confine the polymerization into this protein cage. THS possesses pores that are wide enough to release polymers into solution. The nanoreactor favorably influenced the polymerization of N-isopropyl acrylamide and poly(ethylene glycol)methylether acrylate. Narrowly dispersed polymers with polydispersity indices (PDIs) down to 1.06 were obtained in the protein nanoreactor, while control reactions with a globular protein-catalyst conjugate only yielded polymers with PDIs above 1.84.

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