Clinical Significance of Health Status Assessment Measures in Head and Neck Cancer

The concept of biomaterials has evolved from one of inert mechanical supports with a long-term, biologically inactive role in the body into complex matrices that exhibit selective cell binding, promote proliferation and matrix production, and may ultimately become replaced by newly generated tissues in vivo. Functionalization of material surfaces with biomolecules is critical to their ability to evade immunorecognition, interact productively with surrounding tissues and extracellular matrix, and avoid bacterial colonization. Antibody molecules and their derived fragments are commonly immobilized on materials to mediate coating with specific cell types in fields such as stent endothelialization and drug delivery. The incorporation of growth factors into biomaterials has found application in promoting and accelerating bone formation in osteogenerative and related applications. Peptides and extracellular matrix proteins can impart biomolecule- and cell-specificities to materials while antimicrobial peptides have found roles in preventing biofilm formation on devices and implants. In this progress report, we detail developments in the use of diverse proteins and peptides to modify the surfaces of hard biomaterials in vivo and in vitro. Chemical approaches to immobilizing active biomolecules are presented, as well as platform technologies for isolation or generation of natural or synthetic molecules suitable for biomaterial functionalization.

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Segregated Protein–Cucurbit[7]uril Crystalline Architectures via Modulatory Peptide Tectons

Ramberg

Guagnini

Engilberge

et al. 2021

Chemistry A European J

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One approach to protein assembly involves watersoluble supramolecular receptors that act like glues. Bionanoarchitectures directed by these scaffolds are often systemspecific, with few studies investigating their customization. Herein, the modulation of cucurbituril-mediated protein assemblies through the inclusion of peptide tectons is described. Three peptides of varying length and structural order were N-terminally appended to RSL, a β-propeller building block. Each fusion protein was incorporated into crystalline architectures mediated by cucurbit[7]uril (Q7). A trimeric coiled-coil served as a spacer within a Q7-directed sheet assembly of RSL, giving rise to a layered material of varying porosity. Within the spacer layers, the coiled-coils were dynamic. This result prompted consideration of intrinsi-cally disordered peptides (IDPs) as modulatory tectons. Similar to the coiled-coil, a mussel adhesion peptide (Mefp) also acted as a spacer between protein-Q7 sheets. In contrast, the fusion of a nucleoporin peptide (Nup) to RSL did not recapitulate the sheet assembly. Instead, a Q7-directed cage was adopted, within which disordered Nup peptides were partially "captured" by Q7 receptors. IDP capture occurred by macrocycle recognition of an intrapeptide Phe-Gly motif in which the benzyl group was encapsulated by Q7. The modularity of these protein-cucurbituril architectures adds a new dimension to macrocycle-mediated protein assembly. Segregated protein crystals, with alternating layers of high and low porosity, could provide a basis for new types of materials.

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Fusion protein of RSL and trimeric coiled coil

Wrońska¹,

Rennie²,

Crowley³

2018

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Cover Feature: Segregated Protein–Cucurbit[7]uril Crystalline Architectures via Modulatory Peptide Tectons (Chem. Eur. J. 59/2021)

Ramberg

Guagnini

Engilberge

et al. 2021

Chemistry A European J

View full text Add to dashboard Cite

From the drawing board to the product, crystalline protein assemblies with alternating compact and porous layers were obtained. Trimeric protein RSL, with pseudo‐C6 symmetry, forms honeycomb assemblies in the presence of cucurbit[7]uril. A coiled‐coil fused to the N terminus of RSL re‐forms the honeycomb assembly but with poorly packed spacer layers. Such bio‐supramolecular tectonics could serve the development of biomaterials. More information can be found in the Full Paper by P. B. Crowley et al. (DOI: 10.1002/chem.202103025).

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Małgorzata A. Wrońska

Adding Functions to Biomaterial Surfaces through Protein Incorporation

Segregated Protein–Cucurbit[7]uril Crystalline Architectures via Modulatory Peptide Tectons

Fusion protein of RSL and trimeric coiled coil

Cover Feature: Segregated Protein–Cucurbit[7]uril Crystalline Architectures via Modulatory Peptide Tectons (Chem. Eur. J. 59/2021)

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