Two Complementary Approaches for the Controlled Release of Biomolecules Immobilized via Coiled-Coil Interactions: Peptide Core Mutations and Multivalent Presentation.

We have developed a heterodimeric coiled-coil system based on two complementary peptides, namely (EVSALEK)5 and (KVSALKE)5, or E and K, for the attachment of E-tagged biomolecules onto K-decorated biomaterials. We here explore two approaches to control the strength and the stability of the E/K coiled-coil complex, and thus its potential for the controlled release of biomolecules. Those are Leucine-to-Alanine mutations in the K peptide (4 peptides with 0 to 3 mutations) and multivalent presentation of the E peptide (6 bio-objects from monomeric to dimeric and n-meric). Using E-tagged growth factors and nanoparticles as models, SPR-based assays performed under continuous flow indicated that the release rate was strongly affected by both approaches independently, and that the strength of the capture could be finely tuned over a wide range (apparent dissociation constant from 0.12 pM to 270 nM). Further release assays carried out in well-plates showed that the multivalent presentation only had a significant influence in this setup since the wells were not rinsed under continuous flow.

Co-immobilization of adhesive peptides and VEGF within a dextran-based coating for vascular applications.

UNLABELLED: Multifunctional constructs providing a proper environment for adhesion and growth of selected cell types are needed for most tissue engineering and regenerative medicine applications. In this context, vinylsulfone (VS)-modified dextran was proposed as a matrix featuring low-fouling properties as well as multiple versatile moieties. The displayed VS groups could indeed react with thiol, amine or hydroxyl groups, be it for surface grafting, crosslinking or subsequent tethering of biomolecules. In the present study, a library of dextran-VS was produced, grafted to aminated substrates and characterized in terms of degree of VS modification (%VS), cell-repelling properties and potential for the oriented grafting of cysteine-tagged peptides. As a bioactive coating of vascular implants, ECM peptides (e.g. RGD) as well as vascular endothelial growth factor (VEGF) were co-immobilized on one of the most suitable dextran-VS coating (%VS=ca. 50% of saccharides units). Both RGD and VEGF were efficiently tethered at high densities (ca. 1nmol/cm(2) and 50fmol/cm(2), respectively), and were able to promote endothelial cell adhesion as well as proliferation. The latter was enhanced to the same extent as with soluble VEGF and proved selective to endothelial cells over smooth muscle cells. Altogether, multiple biomolecules could be efficiently incorporated into a dextran-VS construct, while maintaining their respective biological activity. STATEMENT OF SIGNIFICANCE: This work addresses the need for multifunctional coatings and selective cell response inherent to many tissue engineering and regenerative medicine applications, for instance, vascular graft. More specifically, a library of dextrans was first generated through vinylsulfone (VS) modification. Thoroughly selected dextran-VS provided an ideal platform for unbiased study of cell response to covalently grafted biomolecules. Considering that processes such as healing and angiogenesis require multiple factors acting synergistically, vascular endothelial growth factor (VEGF) was then co-immobilized with the cell adhesive RGD peptide within our dextran coating through a relevant strategy featuring orientation and specificity. Altogether, both adhesive and proliferative cues could be incorporated into our construct with additive, if not synergetic, effects.

Tailoring the Surface of a Gene Delivery Vector with Carboxymethylated Dextran: A Systematic Analysis.

Polymeric nanocarriers are attractive nonviral vectors for gene delivery purposes in vivo. For such applications, numerous physiological and subcellular bottlenecks have to be overcome. In that endeavor, each structural feature of nanocarriers can be optimized with respect to its corresponding challenges. Here, we focused on the interface between a model gene delivery nanocarrier and relevant constituents of the physiological environment. We screened a library of carboxymethylated dextrans (CMD) for the electrostatic coating of positively charged nanocarriers. We evaluated the jointed influence of the CMD molecular weight and charge density upon nanocarrier coating with respect to DNase, small ions, plasma proteins, red blood cells, and target cells. A total of 4 out of 26 CMD coated nanocarriers successfully passed every screening assay, but did not yield increased reporter gene expression in target cells compared to uncoated nanocarriers. The fine-tuning of CMD for nanocarrier coating yielded a relevant shortlist of candidates that will be further tested in vivo.

Enhanced ELISA based on carboxymethylated dextran coatings.

In a "sandwich" enzyme-linked immunosorbent assay (ELISA) designed to detect an antigen in a complex protein mixture, the antigen is usually captured via an antibody adsorbed to the wells of a microplate. Plate preparation for standard assay involves a passive adsorption of capture antibodies followed by the incubation of blocking agents. Here, we describe a new strategy that replaces these two time-consuming adsorption steps (up to 15 h) by a unique step corresponding to the covalent grafting of the capture antibody on a carboxymethylated dextran (CMD) layer, a single step completed in 15 min. Taking advantage of the CMD low-fouling properties, blocking agent-free buffer solutions can be used as diluent in the improved approach.

Surface modification of nonviral nanocarriers for enhanced gene delivery.

Biomedical nanotechnology has given a new lease of life to gene therapy with the ever-developing and ever-diversifying nonviral gene delivery nanocarriers. These are designed to pass a series of barriers in order to bring their nucleic acid cargo to the right subcellular location of particular cells. For a given application, each barrier has its dedicated strategy, which translates into a physicochemical, biological and temporal identity of the nanocarrier surface. Different strategies have thus been explored to implement adequate surface identities on nanocarriers over time for systemic delivery. In that context, this review will mainly focus on organic nanocarriers, for which these strategies will be described and discussed.

A versatile coiled-coil tethering system for the oriented display of ligands on nanocarriers for targeted gene delivery.

Surface modification of non-viral gene delivery nanocarriers may provide advanced features such as receptor targeting, endosomal escape and nuclear import. We here report the design of a versatile and tunable immobilization protocol to functionalize nanocarriers for improved transient gene expression. Our strategy is based on specific interactions occurring between a coil-tagged ligand and a complementary coil-functionalized nanocarrier. As a proof of concept, targeting of DNA/polyethylenimine polyplexes to the epidermal growth factor receptor of A431 cells was investigated. Coiled-coil-mediated oriented tethering of epidermal growth factor triggered a drastic increase of the internalization rate of the targeted polyplexes. To explore the tunability of our platform, surface density of targeting ligand was varied; our results indicated that the internalization rate varied with the ligand-to-polyplex ratio in a "switch mode" fashion. This work prefigures possible avenues for our coiled-coil platform in multiplex functionalization to address transient gene expression bottlenecks in recombinant protein production.