Preferential cross-linking of the stereospecific complex over the encounter complexes by DOPA2, a faster cross-linker than DSS

Transient protein-protein interactions are fundamental aspects of many biochemical reactions, but they are technically challenging to study. Chemical cross-linking of proteins coupled with mass spectrometry (CXMS) analysis is a powerful tool to facilitate the analysis of transient interactions. Central to this technology are chemical cross-linkers. Here, using two transient heterodimeric complexes--EIN/HPr with a KD of 7 M and EIIAGlc/EIIBGlc with a KD of 25 M--as model systems, we compared the effects of two amine-specific homo-bifunctional cross-linkers of different cross-linking speeds. Protein cross-linking by DOPA2, a di-ortho-phthalaldehyde cross-linker, is 60-120 times faster than that by DSS, an N-hydroxysuccinimide ester cross-linker. We analyzed the differences in the number of cross-links identified that reflected the stereospecific complex (SC), the final lowest-energy conformational state, and that of cross-links that reflected the encounter complexes (ECs), an ensemble of short-lived intermediate conformations mediated by nonspecific electrostatic interactions. We found that the faster DOPA2 cross-linking favored the SC whereas the slower DSS cross-linking favored the ECs. We propose a mechanistic model for this intriguing observation. This study suggests that it is feasible to probe the dynamics of protein-protein interaction using cross-linkers of different cross-linking speeds.