Madhavan Nallani

Single-Step Azide Introduction in Proteins via an Aqueous Diazo Transfer

The controlled introduction of azides in proteins provides targetable handles for selective protein manipulation. We present here an efficient diazo transfer protocol that can be applied in an aqueous solution, leading to the facile introduction of azides in the side chains of lysine residues and at the N-terminus of enzymes, e.g. horseradish peroxidase (HRP) and the red fluorescent protein DsRed. The effective introduction of azides was verified by mass spectrometry, after which the azido-proteins were used in Cu(I)-catalyzed [3 + 2] cycloaddition reactions. Azido-HRP retained its catalytic activity after conjugation of a small molecule. This modified protein could also be successfully immobilized on the surface of an acetylene-covered polymersome. Azido-DsRed was coupled to an acetylene-bearing protein allowing it to act as a fluorescent label, demonstrating the wide applicability of the diazo transfer procedure.

Proteopolymersomes: In vitro production of a membrane protein in polymersome membranes

Polymersomes are stable self-assembled architectures which mimic cell membranes. For characterization, membrane proteins can be incorporated into such bio-mimetic membranes by reconstitution methods, leading to so-called proteopolymersomes. In this work, we demonstrate the direct incorporation of a membrane protein into polymersome membranes by a cell-free expression system. Firstly, we demonstrate pore formation in the preformed polymersome membrane using α-hemolysin. Secondly, we use claudin-2, a protein involved in cell-cell interactions, to demonstrate the in vitro expression of a membrane protein into these polymersomes. Surface plasmon resonance (Biacore) binding studies with the claudin-2 proteopolymersomes and claudin-2 specific antibodies are performed to show the presence of the in vitro expressed protein in polymersome membranes.

Self-assembled architectures with multiple aqueous compartments

A vital organizational feature of living cells is that of compartmentalization. This allows cells to run concurrently incompatible metabolic processes and to regulate these processes by selective trans-membrane transport. Although strategies that effectively mimic cell function in simple architectures have been researched extensively, soft matter systems with membranes that delineate distinct and multiple aqueous environments have only recently caught attention. We highlight a range of multi-compartmentalized soft matter systems including vesosomes, capsosomes, polymersomes, double emulsions, and their combinations, and demonstrate that the unique properties of the multi-compartmentalized architectures have the potential to add value to application areas such as drug-delivery and multi-enzyme biosynthesis.

In vitro expressed GPCR inserted in polymersome membranes for ligand-binding studies

The dopamine receptor D2 (DRD2), a G-protein coupled receptor is expressed into PBd(22)-PEO(13) and PMOXA(20)-PDMS(54)-PMOXA(20) block copolymer vesicles. The conformational integrity of the receptor is confirmed by antibody- and ligand-binding assays. Replacement of bound dopamine is demonstrated on surface-immobilized polymersomes, thus making this a promising platform for drug screening.

An intercompartmental enzymatic cascade reaction in channel-equipped polymersome-in-polymersome architectures

Compartmentalization, as a design principle, is a prerequisite for the functioning of eukaryotic cells. Although cell mimics in the form of single vesicular compartments such as liposomes or polymersomes have been tremendously successful, investigations of the corresponding higher-order architectures, in particular bilayer-based multicompartment vesicles, have only recently gained attention. We hereby demonstrate a multicompartment cell-mimetic nanocontainer, built-up from fully synthetic membranes, which features an inner compartment equipped with a channel protein and a semi-permeable outer compartment that allows passive diffusion of small molecules. The functionality of this multicompartment architecture is demonstrated by a cascade reaction between enzymes that are segregated in separate compartments. The unique architecture of polymersomes, which combines stability with a cell-membrane-mimetic environment, and their assembly into higher-order architectures could serve as a design principle for new generation drug-delivery vehicles, biosensors, and protocell models.

A facile and fast method for the functionalization of polymersomes by photoinduced cycloaddition chemistry

Polymersomes are promising platforms for use in biosensing, where their stability may be crucial over that of liposomes. For the introduction of the desired functionality multiple strategies have been reported for functionalization of polymersomes. However, none of them have combined readily available starting materials, facility and in situ quantification. We show a simple 4-step method for functionalization of polymersomes starting from commercially available materials. For the key conjugation step a recently explored light induced cycloaddition was used which is relatively fast (15 min) and allows in situ quantification by the intrinsic fluorescence of the conjugate. The facility of the protocol, the ease of preparation and quantification make this ‘click’-type conjugation method a promising alternative to the established strained cycloadditions.

Selective Deposition and Self-Assembly of Triblock Copolymers into Matrix Arrays for Membrane Protein Production

To improve the stability of cell membrane mimics, there has been growing interest in the use of block copolymers. Here, we present an easy approach to create an array of planar polymeric matrices capable of hosting membrane proteins. The array of polymeric matrices was formed by the selective deposition of triblock copolymers onto an array of hydrophilic islands situated within a hydrophobic background. The thickness of these matrices corresponds to the length of a single polymer chain. These polymeric matrices were used to host cell-free expressed membrane proteins, and offers a prototype from which a membrane protein array can be created for diagnostics or drug discovery purposes.

Third-Party ATP Sensing in Polymersomes: A Label-Free Assay of Enzyme Reactions in Vesicular Compartments

Polymersomes are encapsulated with a fluorescent reporter and a non-labeled enzyme for sensing of adenosine triphosphate (ATP). As B. Liedberg and co-workers report on page 442, passive diffusion of exogenously added ATP through the membrane is sensed by monitoring the ATPinduced fluorescence quenching of the reporter polymer followed by partial recovery of its emission due to hydrolysis of reporter-bound ATP by alkaline phosphatase.

Mixing, diffusion, and percolation in binary supported membranes containing mixtures of lipids and amphiphilic block copolymers.

Substrate-mediated fusion of small polymersomes, derived from mixtures of lipids and amphiphilic block copolymers, produces hybrid, supported planar bilayers at hydrophilic surfaces, monolayers at hydrophobic surfaces, and binary monolayer/bilayer patterns at amphiphilic surfaces, directly responding to local measures of (and variations in) surface free energy. Despite the large thickness mismatch in their hydrophobic cores, the hybrid membranes do not exhibit microscopic phase separation, reflecting irreversible adsorption and limited lateral reorganization of the polymer component. With increasing fluid-phase lipid fraction, these hybrid, supported membranes undergo a fluidity transition, producing a fully percolating fluid lipid phase beyond a critical area fraction, which matches the percolation threshold for the immobile point obstacles. This then suggests that polymer-lipid hybrid membranes might be useful models for studying obstructed diffusion, such as occurs in lipid membranes containing proteins.

Conformational antibody binding to a native, cell-free expressed GPCR in block copolymer membranes.

G-protein coupled receptors (GPCRs) play a key role in physiological processes and are attractive drug targets. Their biophysical characterization is, however, highly challenging because of their innate instability outside a stabilizing membrane and the difficulty of finding a suitable expression system. We here show the cell-free expression of a GPCR, CXCR4, and its direct embedding in diblock copolymer membranes. The polymer-stabilized CXCR4 is readily immobilized onto biosensor chips for label-free binding analysis. Kinetic characterization using a conformationally sensitive antibody shows the receptor to exist in the correctly folded conformation, showing binding behaviour that is commensurate with heterologously expressed CXCR4.