Probing multivalency in ligand-receptor-mediated adhesion of soft, biomimetic interfaces.

Many biological functions at cell level are mediated by the glycocalyx, a dense carbohydrate-presenting layer. In this layer specific interactions between carbohydrate ligands and protein receptors are formed to control cell-cell recognition, cell adhesion and related processes. The aim of this work is to shed light on the principles of complex formation between surface anchored carbohydrates and receptor surfaces by measuring the specific adhesion between surface bound mannose on a concanavalin A (ConA) layer via poly(ethylene glycol)-(PEG)-based soft colloidal probes (SCPs).

A novel contact model for AFM indentation experiments on soft spherical cell-like particles.

The use of the simple Hertz model for the analysis of Atomic Force Microscopy (AFM) force-distance curves measured on soft spherical cell-like particles leads to significant underestimations of the objects Young's modulus E. To correct this error, a mixed double contact model (based on the simple Hertz model and the Johnson-Kendall-Roberts (JKR) model) was derived. The model considers two independent particle deformation sites: (i) the upper part of the particle is deformed by the AFM indenter, (ii) the bottom part is deformed by the substrate, which is usually unnoticed.

Specific adhesion of carbohydrate hydrogel particles in competition with multivalent inhibitors evaluated by AFM.

Synthetic glycooligomers have emerged as valuable analogues for multivalent glycan structures in nature. These multivalent carbohydrates bind to specific receptors and play a key role in biological processes. In this work, we investigate the specific interaction between mannose ligand presenting soft colloidal probes (SCPs) attached to an atomic force microscope (AFM) cantilever and a Concanavalin A (ConA) receptor surface in the presence of competing glycooligomer ligands.

Metal-mediated molecular self-healing in histidine-rich mussel peptides.

Mussels withstand high-energy wave impacts in rocky seashore habitats by fastening tightly to surfaces with tough and self-healing proteinaceous fibers called byssal threads. Thread mechanical behavior is believed to arise from reversibly breakable metal coordination cross-links embedded in histidine-rich protein domains (HRDs) in the principle load-bearing proteins comprising the fibrous thread core. In order to investigate HRD behavior at the molecular level, we have synthesized a histidine-rich peptide derived from mussel proteins (His5-bys) and studied its reversible adhesive self-interaction in the presence and absence of metal ions using PEG-based soft-colloidal probes (SCPs).

Carbohydrate-lectin recognition of sequence-defined heteromultivalent glycooligomers.

Multivalency as a key principle in nature has been successfully adopted for the design and synthesis of artificial glycoligands by attaching multiple copies of monosaccharides to a synthetic scaffold. Besides their potential in various applied areas, e.g.

Mechanical carbohydrate sensors based on soft hydrogel particles.

Elastic sensors: A simple method is presented for the measurement of specific biomolecular interactions with soft colloidal hydrogel particles (SCPs) as sensors. Carbohydrate/lectin interactions (see picture; green: carbohydrate molecules) were studied by optical detection of the mechanical deformation of the particles on a lectin surface. The affinity of various carbohydrate inhibitors could also be readily determined.