Abstract
Hollow vesicles made from a single or double layer of block-copolymer molecules, called polymersomes, represent an important technological platform for new developments in nano-medicine and nano-biotechnology. A central aspect in creating functional polymersomes is their combination with proteins, especially through encapsulation in the inner cavity of the vesicles. When producing polymersomes by techniques such as film rehydration, significant proportions of the proteins used are trapped in the vesicle lumen, resulting in high encapsulation efficiencies. However, because of the difficulty of scaling up, such methods are limited to laboratory experiments and are not suitable for industrial scale production. Recently, we developed a scalable polymersome production process in stirred-tank reactors, but the statistical encapsulation of proteins resulted in fairly low encapsulation efficiencies of around 0.5%. To increase encapsulation in this process, proteins were genetically fused with hydrophobic membrane anchoring peptides. This resulted in encapsulation efficiencies of up to 25.68%. Since proteins are deposited on the outside and inside of the polymer membrane in this process, two methods for the targeted removal of protein domains by proteolysis with tobacco etch virus protease and intein splicing were evaluated. This study demonstrates the proof-of-principle for production of protein-functionalized polymersomes in a scalable process.
Highlights
Via the self-assembly in aqueous solution, block-copolymers can form hollow, spherical vesicles, called polymersomes [1]
The membrane anchoring peptides originated from rabbit liver cytochrome b5 (Cytb5 ), the lysis protein L from the SM2 phage (L’), the syntaxin Vam3p (Vam3p’) and the ubiquitin conjugating enzyme 6 (UBC6 ) from yeast [22]
The proteins were applied in concentrations of 0.50 g/L before starting polymersome formation, with the exception of enhanced green fluorescent protein (eGFP)-UBC6, which was used at 0.40 g/L due to low protein expression yields
Summary
Via the self-assembly in aqueous solution, block-copolymers can form hollow, spherical vesicles, called polymersomes [1]. These vesicles are composed of a polymer membrane of a single or double layer of short linear polymer molecules. Triblock-copolymers of the ABA type, in which the outer blocks (A) are hydrophilic and the inner (B) block is hydrophobic, form vesicles with a single layer, in which the linear block-copolymer chains arrange themselves alongside in order to minimize exposure of the central hydrophobic block to the aqueous surrounding [2]. One type of ABA triblock-copolymer is PMOXA-PDMS-PMOXA (poly(2-methoxazoline)-bpoly(dimethylsiloxane)-b-poly(2-methoxazoline)) It has been used in a number of polymersome designs, which combined the polymersomes with proteins, creating functionalized polymersomes (e.g., [4,5,6,7,8]). The outer PMOXA blocks display low protein binding properties and are biocompatible [11], making this block-copolymer an interesting material for biotechnological and, in particular, medical applications
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