•Antibody fragments retain the binding characteristics of the complete antibody.•Non-antibody protein scaffolds with loops serve as alternative binding molecules.•Synthetic paratope mimetic peptides presenting CDRs are functional antibody mimics.The rational/structure-based design and/or combinatorial development of molecules capable of selectively binding to a protein, represents a promising strategy for a range of biomedical applications, in particular the inhibition of disease-associated protein–ligand interactions. The design of such protein binding molecules is often based on an antibody against the target protein, or involves the generation of smaller molecules that retain the binding characteristics of the antibody. Alternatively, protein binding molecules can be selected from protein libraries based on small, stably folded protein scaffolds presenting flexible loops, which are randomized in the libraries. In addition to recombinantly synthesized molecules, synthetic antibody paratope mimetic peptides have emerged as promising molecules for the design of antibody mimics.

C 3-Symmetric trimesic acid scaffolds, functionalized with bromoacetyl, aminooxyacetyl and azidoacetyl moieties, respectively, were synthesized and compared regarding their utility for the trivalent presentation of peptides using three different chemoselective ligation reactions, i.e. thioether and oxime formation, as well as the “click” reaction. The latter ligation method was then used to covalently stabilize the trimer of foldon, a 27 amino acid trimerization domain of bacteriophage T4 fibritin, by linking the three foldon monomers to the triazido-functionalized trimesic acid scaffold. This reaction dramatically enhanced the thermal stability of the trimer, while maintaining the correct fold, as demonstrated by CD spectroscopy and X-ray crystal structure analysis, respectively, of the foldon–scaffold conjugates.

C 3-Symmetric trimesic acid scaffolds, functionalized with bromoacetyl, aminooxyacetyl and azidoacetyl moieties, respectively, were synthesized and compared regarding their utility for the trivalent presentation of peptides using three different chemoselective ligation reactions, i.e. thioether and oxime formation, as well as the “click” reaction. The latter ligation method was then used to covalently stabilize the trimer of foldon, a 27 amino acid trimerization domain of bacteriophage T4 fibritin, by linking the three foldon monomers to the triazido-functionalized trimesic acid scaffold. This reaction dramatically enhanced the thermal stability of the trimer, while maintaining the correct fold, as demonstrated by CD spectroscopy and X-ray crystal structure analysis, respectively, of the foldon–scaffold conjugates.