Clustering of Giant Unilamellar Vesicles Promoted by Covalent and Noncovalent Bonding of Functional Groups at Membrane-Embedded Peptides.

Access to clusters of cell-sized globular objects such as giant unilamellar vesicles (GUVs) is of increasing interest due to their potential applications in prototissue and cell-cell adhesion studies. Aggregations of GUVs by four different approaches were observed via covalent as well as noncovalent bond participations of functional groups at membrane embedded cholesterylpeptides using optical microscopy. Passive air oxidation of GUV-surface thiols into trans-GUV disulfide bonds promoted multivesicle aggregation. Aggregations of GUVs into multiclusters were also achieved by introduction of bispyridyl-ligand substituted peptides into GUV-membranes succeeded by rhodium diacetate mediated vesicle clustering and, furthermore, by coinstalling a biotin moiety streptavidin addition attenuating the clustering effect visualized by formation of compact superaggregated GUV-multiclusters. Contacting between two different GUV-populations, i.e., GUV-heteroconnection, was achieved by trans-GUV phenyl ester-hydrazine ligations producing GUV-heteroclusters. Indirectly, GUV-clustering was achieved by strain-promoted azide-alkyne cycloaddition (SPAAC) reacting bicyclononyne (BCN)-GUVs with azido-GlcNAc succeeded by biotinylated wheat germ agglutinin (WGA)-lectin/streptavidin incubation arousing cross-binding of GUVs.

ABO Blood Group Antigen Decorated Giant Unilamellar Vesicles Exhibit Distinct Interactions with Plasmodium falciparum Infected Red Blood Cells.

Severe malaria is considered to be the deadliest disease of this century, primarily among children in sub-Saharan Africa. It stems from infection by the virulent parasite Plasmodium falciparum. The pathogenesis of the disease is based on the rosetting phenomenon, which occurs during the life cycle of the parasite in red blood cells (RBCs) and promotes the binding of parasitized RBCs to healthy ones. The role of the ABO blood group antigens in relation to the phenomenon has previously only been investigated in clinical isolates obtained from malaria patients. Here, we aim to clarify their role using synthetic ABO-decorated giant unilamellar vesicles (GUVs), which serve as simple biomimetic models of RBC-size cell membranes. Our results suggest clearly and for the first time that the blood group A and O antigens have a direct impact on receptor-specific rosetting phenomena when compared to the B antigen, which only participates in rosetting to an insignificant degree. Thus, glycodecorated GUVs represent a practical tool for studying cell-surface interactions.

Synthesis of BODIPY-Labeled Cholesterylated Glycopeptides by Tandem Click Chemistry for Glycocalyxification of Giant Unilamellar Vesicles (GUVs).

The glycocalyx cover membrane surfaces of all living cells. These complex architectures render their interaction mechanisms on the membrane surface difficult to study. Artificial cell-sized membranes with selected and defined glycosylation patterns may serve as a minimalistic approach to systematically study cell surface glycan interactions. The development of a facile general synthetic procedure for the synthesis of BODIPY-labeled cholesterylated glycopeptides, which can coat cell-size giant unilamellar vesicles (GUVs), is described. These peptide constructs were synthesized by: 1) solid-phase peptide synthesis (SPPS) using cholesterylated Fmoc-amino acids (Fmoc=9-fluorenylmethoxycarbonyl) followed by tandem click reactions, 2) attachment of a BODIPY-bicyclononyne (BCN) (prepared by Mitsunobu chemistry via novel aryl BCN-ethers) in the absence of a catalyst, and 3) glycosylation by means of copper(I)-catalyzed click reaction of an azidoglycan. Seven different GUV-glycoforms were prepared and four of these were evaluated with their corresponding four specific anti-glycan binding lectins.