The length of the N-terminal region of a photocleavable peptide bound to DR1 determines the kinetics of photocleavable peptide fragment release

Abstract

Abstract MHC class II molecules (MHCII) bind peptides and present them to CD4+ T cells. As prepared as a recombinant protein, DR1 (a MHCII) is in equilibrium between peptide-receptive and peptide-averse conformations. In order to dissect which step of the peptide binding reaction is being affected in DR1 mutants with altered peptide affinity, we wanted to generate DR1 fully in the peptide-receptive conformation. To generate this form, we used a peptide carrying the photocleavable 3-amino-3-(2-nitrophenyl)-propionic acid residue, an approach previously used for other MHCI and MHCII proteins. We used variants of a well-characterized peptide derived from influenza hemagglutinin (HA), with different truncations at the N-terminal end, expecting to generate peptides with different affinity for DR1. This was confirmed by higher IC50 values obtained for the shorter peptides compared to the longer ones. All of the studied peptides were cleaved as expected after UV treatment as shown by mass spectrometry. However, when DR1-photocleavable peptide complexes were exposed to UV light, they generated different amounts of peptide-receptive DR1 measured by their ability to bind fluorescently-labeled HA peptide. The shorter the peptide, the more peptide-receptive DR1 was generated. This suggests that minimizing the interaction between photocleavable peptide and DR1 allows faster dissociation of the photo-generated fragments, and thus faster association of an incoming peptide. These results showed that the kinetics of photocleavable peptide fragment release can interfere with the kinetics of subsequent reactions.