26 research outputs found
Cucurbit[8]uril induced heterodimerization of methylviologen and naphthalene functionalized proteins
Cucurbit[8]uril is a supramolecular inducer of protein heterodimerization for proteins appended with methylviologen and naphthalene host elements. Two sets of fluorescent protein pairs, which visualize the specific protein assembly process, enabled the interplay of the supramolecular elements with the proteins to be established
Directed supramolecular surface assembly of SNAP-tag fusion proteins
Supramolecular assembly of proteins on surfaces and vesicles was investigated by site-selective incorporation of a supramolecular guest element on proteins. Fluorescent proteins were site-selectively labeled with bisadamantane by SNAP-tag technology. The assembly of the bisadamantane functionalized SNAP-fusion proteins on cyclodextrin-coated surfaces yielded stable monolayers. The binding of the fusion proteins is specific and occurs with an affinity in the order of 106ÂżM-1 as determined by surface plasmon resonance. Reversible micropatterns of the fusion proteins on micropatterned cyclodextrin surfaces were visualized by using fluorescence microscopy. Furthermore, the guest-functionalized proteins could be assembled out of solution specifically onto the surface of cyclodextrin vesicles. The SNAP-tag labeling of proteins thus allows for assembly of modified proteins through a hostâguest interaction on different surfaces. This provides a new strategy in fabricating protein patterns on surfaces and takes advantage of the high labeling efficiency of the SNAP-tag with designed supramolecular elements
Immobilization of ferrocene-modified SNAP-fusion proteins
Abstract: The supramolecular assembly of proteins on surfaces has been investigated via the site-selective incorporation of a supramolecular moiety on proteins. To this end, fluorescent proteins have been site-selectively labeled with ferrocenes, as supramolecular guest moieties, via SNAP-tag technology. The assembly of guest-functionalized SNAP-fusion proteins on cyclodextrin-and cucurbi
Immobilization of ferrocene-modified SNAP-fusion proteins
The supramolecular assembly of proteins on surfaces has been investigated via the site-selective incorporation of a supramolecular moiety on proteins. To this end, fluorescent proteins have been site-selectively labeled with ferrocenes, as supramolecular guest moieties, via SNAP-tag technology. The assembly of guest-functionalized SNAP-fusion proteins on cyclodextrin- and cucurbit[7]uril-coated surfaces yielded stable monolayers. The binding of all ferrocene fusion proteins is specific as determined by surface plasmon resonance. Micropatterns of the fusion proteins, on patterned cyclodextrin and cucurbituril surfaces, have been visualized using fluorescence microscopy. The SNAP-fusion proteins were also immobilized on cyclodextrin vesicles. The supramolecular SNAP-tag labeling of proteins, thus, allows for the assembly of modified proteins via supramolecular host-guest interaction on different surfaces in a controlled manner. These findings extend the toolbox of fabricating supramolecular protein patterns on surfaces taking advantage of the high labeling efficiency of the SNAP-tag with versatile supramolecular moietie