N-Terminal dual protein functionalization by strain-promoted alkyne-nitrone cycloaddition.

Strain-promoted alkyne-nitrone cycloadditon (SPANC) was optimized as a versatile strategy for dual functionalization of peptides and proteins. The usefulness of the dual labeling protocol is first exemplified by the simultaneous introduction of a chloroquine and a stearyl moiety, two endosomal escape-improving functional groups, into the cell-penetrating peptide hLF (human lactoferrin). Additionally, we demonstrate that dual labeling of proteins is feasible by combining metal-free and copper-catalyzed click chemistry. First, SPANC is applied to enhanced green fluorescent protein to introduce both biotin and a terminal alkyne. The terminal acetylene then serves as a convenient anchor point for the CuAAC reaction with azido-containing fluorescein, thereby demonstrating the potential of combined SPANC and CuAAC for the straightforward, dual functionalization of proteins.

Protein enrichment by capture-release based on strain-promoted cycloaddition of azide with bicyclononyne (BCN).

An enrichment strategy was devised for azide derivatized macromolecules, based on strain-promoted alkyne-azide cycloaddition (SPAAC) and a cleavable linker. A ring-strained alkyne, bicyclo[6.1.0]non-4-yne (BCN), was covalently attached to agarose beads via a hydrazine-sensitive linker. Benchmark studies of the resulting 'azido-trap' beads were performed with a fluorogenic coumarin derivative, leading to efficient capture of the azidocoumarin with concomitant fluorescence staining of the beads via SPAAC. The versatility of the beads for specific protein enrichment was shown by an effective and highly specific capture-release strategy for enrichment of azido-containing Candida antarctica lipase B (CalB) from a mixture of proteins. This approach is suited for selective enrichment of (glyco)proteins after metabolic incorporation of azides for subsequent (glyco)proteomics studies.

Collagen targeting using multivalent protein-functionalized dendrimers.

Collagen is an attractive marker for tissue remodeling in a variety of common disease processes. Here we report the preparation of protein dendrimers as multivalent collagen targeting ligands by native chemical ligation of the collagen binding protein CNA35 to cysteine-functionalized dendritic divalent (AB(2)) and tetravalent (AB(4)) wedges. The binding of these multivalent protein constructs was studied on collagen-immobilized chip surfaces as well as to native collagen in rat intestinal tissues. To understand the importance of target density we also created collagen-mimicking surfaces by immobilizing synthetic collagen triple helical peptides at various densities on a chip surface. Multivalent display of a weak-binding variant (CNA35-Y175K) resulted in a large increase in collagen affinity, effectively restoring the collagen imaging capacities for the AB(4) system. In addition, dissociation of these multivalent CNA35 dendrimers from collagen surfaces was found to be strongly attenuated.