Reversible and Oriented Immobilization of Ferrocene-Modified Proteins

Abstract: Adopting supramolecular chemistry for immobilization of proteins is an attractive strategy that entails reversibility and responsiveness to stimuli. The reversible and oriented immobilization and micropatterning of ferrocene-tagged yellow fluorescent proteins (Fc-YFPs) onto β-cyclodextrin (βCD) molecular printboards was characterized using surface plasmon resonance (SPR) spectroscopy and fluorescence microscopy in combination with electrochemistry. The proteins were assembled on the surface through the specifi… Show more

“…In this respect, we linked a yellow fluorescent protein (YFP) bearing a C-terminal thioester to a cysteine-functionalized ferrocene via expressed protein ligation (Fig. 5) [16,17]. We first exploited the interaction of these ferrocenylated YFPs with self-assembled monolayers (SAMs) of CB [7] (Fig.…”

“…A number of Fc-YFP constructs with different ferrocene valencies, (mono-and divalent) were generated by making use of the construct's intrinsic affinity for noncovalent homodimerization as well as cysteine residues for covalent homodimerization via the formation of disulfide bonds (Fig. 6) [17]. In short, one variant (Fc-dYFP) contained two point mutations that increased the affinity for noncovalent dimerization, while the so-called enhanced variant (Fc-eYFP) lacked these dimerization-promoting mutations [17].…”

“…6) [17]. In short, one variant (Fc-dYFP) contained two point mutations that increased the affinity for noncovalent dimerization, while the so-called enhanced variant (Fc-eYFP) lacked these dimerization-promoting mutations [17]. In addition we made use of the fact that expressed chemical ligation leads to the formation of a cysteine residue (Fig.…”

“…The cysteine residues of the Fc-YFP constructs, are situated in such a way that they are amenable to the formation of covalent disulfide crosslinks via oxidation [17]. In a control variant (Fc-bYFP), the cysteine residues of the monovalent constructs were blocked by reaction with N-methylmaleimide [17]. The different Fc-YFP variants were assembled on SAMs of bCD [17].…”

Redox-active host-guest supramolecular assemblies of peptides and proteins at surfaces

“…In this respect, we linked a yellow fluorescent protein (YFP) bearing a C-terminal thioester to a cysteine-functionalized ferrocene via expressed protein ligation (Fig. 5) [16,17]. We first exploited the interaction of these ferrocenylated YFPs with self-assembled monolayers (SAMs) of CB [7] (Fig.…”

“…A number of Fc-YFP constructs with different ferrocene valencies, (mono-and divalent) were generated by making use of the construct's intrinsic affinity for noncovalent homodimerization as well as cysteine residues for covalent homodimerization via the formation of disulfide bonds (Fig. 6) [17]. In short, one variant (Fc-dYFP) contained two point mutations that increased the affinity for noncovalent dimerization, while the so-called enhanced variant (Fc-eYFP) lacked these dimerization-promoting mutations [17].…”

“…6) [17]. In short, one variant (Fc-dYFP) contained two point mutations that increased the affinity for noncovalent dimerization, while the so-called enhanced variant (Fc-eYFP) lacked these dimerization-promoting mutations [17]. In addition we made use of the fact that expressed chemical ligation leads to the formation of a cysteine residue (Fig.…”

“…The cysteine residues of the Fc-YFP constructs, are situated in such a way that they are amenable to the formation of covalent disulfide crosslinks via oxidation [17]. In a control variant (Fc-bYFP), the cysteine residues of the monovalent constructs were blocked by reaction with N-methylmaleimide [17]. The different Fc-YFP variants were assembled on SAMs of bCD [17].…”

Redox-active host-guest supramolecular assemblies of peptides and proteins at surfaces

“…By incorporation of theses ynthetic receptors on as olids upport, proteins containing the correspondingl igand can be immobilized. [20,26,[31][32][33][34][35][36][37][38][39] There are, however, only very limited examples of the use of supramolecular chemistry fort he immobilization of proteins on lipid bilayers. The potentialo f as upramolecular approach forp rotein immobilization on lipid membranes is most impressively illustrated by the membrane incorporation of nitrilotriacetic acids that recruit His 6 -tagged proteins upon addition of nickel.…”

Supramolecular Protein Immobilization on Lipid Bilayers

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