Specificity of Molecular Fragments Binding to S100B versus S100A1 as Identified by NMR and Site Identification by Ligand Competitive Saturation (SILCS).

Brianna D Young,David J Weber,Alexander D Mackerell,Wenbo Yu,Kristen M Varney,Darex J Vera Rodríguez

doi:10.3390/molecules26020381

Abstract

S100B, a biomarker of malignant melanoma, interacts with the p53 protein and diminishes its tumor suppressor function, which makes this S100 family member a promising therapeutic target for treating malignant melanoma. However, it is a challenge to design inhibitors that are specific for S100B in melanoma versus other S100-family members that are important for normal cellular activities. For example, S100A1 is most similar in sequence and structure to S100B, and this S100 protein is important for normal skeletal and cardiac muscle function. Therefore, a combination of NMR and computer aided drug design (CADD) was used to initiate the design of specific S100B inhibitors. Fragment-based screening by NMR, also termed “SAR by NMR,” is a well-established method, and was used to examine spectral perturbations in 2D [1H, 15N]-HSQC spectra of Ca2+-bound S100B and Ca2+-bound S100A1, side-by-side, and under identical conditions for comparison. Of the 1000 compounds screened, two were found to be specific for binding Ca2+-bound S100A1 and four were found to be specific for Ca2+-bound S100B, respectively. The NMR spectral perturbations observed in these six data sets were then used to model how each of these small molecule fragments showed specificity for one S100 versus the other using a CADD approach termed Site Identification by Ligand Competitive Saturation (SILCS). In summary, the combination of NMR and computational approaches provided insight into how S100A1 versus S100B bind small molecules specifically, which will enable improved drug design efforts to inhibit elevated S100B in melanoma. Such a fragment-based approach can be used generally to initiate the design of specific inhibitors for other highly homologous drug targets.

Highlights

S100 proteins are dimeric EF-hand proteins that exhibit diverse protein-protein interactions upon Ca2+-binding [1]
In cardiac and skeletal muscle, S100A1 interacts with the ryanodine receptor to promote sarcoplasmic reticulum (SR) calcium release and S100A1, but not S100B, regulates protein kinase A signaling in muscle and the nervous system, to name a few [5,8,9]
S100A1 is up-regulated in a disease-specific manner, so developing S100A1-specific inhibitors may aid in treating diabetes, neurological diseases, heart failure, and other cancers [5,10,11,12,13,14]

Summary

Introduction

S100 proteins are dimeric EF-hand proteins that exhibit diverse protein-protein interactions upon Ca2+-binding [1]. At Site 2, Molecules 2021, 26, x FORS1PE0E0RAR1EhVaIEsWmore favorable bindings from apolar and hydrogen bonding acceptor and 10 of donor types compared to S100B Such information can be used to design specific binders and helps explain the specificity of the fragments to the two proteins, as identified by NMR. The two terminal hydroxyl groups can form hydrogen bonding with backbone carbonyl groups in residues E45 and M79, which is confirmed by large NMR CSPs (Figure 3) All these interactions with Site 1 residues make fragment BTB10184 the best binder to S100B among the three. For the dual-binder BTB10184, the LGFE score shows that it favors binding to S100B over S100A1, and this is consistent with its much stronger perturbation results for S100B over S100A1

Discussion

Screening and NMR Data Collection

Structure Models for S100B and S100A1

SILCS Simulation

SILCS-Hotspots Analyses

Conclusions