Biophysical properties of the isolated spike protein binding helix of human ACE2

Abstract

\n The entry of the SARS-CoV2 virus in human cells is mediated by the binding of its surface spike protein to the human Angiotensin-Converting Enzyme 2 (ACE2) receptor. A 23 residues long helical segment (SBP1) at the binding interface of human ACE2 interacts with viral spike protein and therefore, has generated considerable interest as a recognition element for virus detection. Unfortunately, emerging reports indicate that the affinity of SBP1 to the receptor-binding domain (RBD) of the spike protein is much lower than that of the ACE2 receptor itself. Here, we examine the biophysical properties of SBP1 to reveal factors leading to its low affinity for the spike protein. While SBP1 shows good solubility (solubility > 0.8 mM), CD spectroscopy shows that it is mostly disordered with some anti-parallel beta-sheet content, and no helicity. The helicity is substantial (> 20%) only upon adding high concentrations (≥ 20% v/v) of 2,2,2-trifluoroethanol, a helix-promoter. Fluorescence correlation spectroscopy and single molecule photobleaching studies show that the peptide oligomerizes at concentrations > 50 nM. We hypothesized that mutating the hydrophobic residues (F28, F32, and F40) of SBP1 which do not directly interact with the spike protein to alanine would reduce peptide oligomerization without affecting its spike binding affinity. While the mutant peptide (SBP1mod) shows substantially reduced oligomerization propensity, it does not show improved helicity. Our study shows that the failure of efforts so far to produce a short SBP1 mimic with a high affinity for the spike protein is not only due to the lack of helicity, but also due to the heretofore unrecognized problem of oligomerization.\n