Structure-Based Design, Docking and Binding Free Energy Calculations of A366 Derivatives as Spindlin1 Inhibitors.

Chiara Luise,Dmytro Ostrovskyi,Ludwig Seifert,Holger Greschik,Dina Robaa,Manfred Jung,Tobias Wagner,Jian Jin,Bernhard Breit,Wolfgang Sippl,Teresa Burgahn,Johannes Seitz,David Maurer,Yan Xiong,Pierre Regenass,Johannes Bacher,Kwang-Su Park,Roland Schüle

doi:10.3390/ijms22115910

Abstract

The chromatin reader protein Spindlin1 plays an important role in epigenetic regulation, through which it has been linked to several types of malignant tumors. In the current work, we report on the development of novel analogs of the previously published lead inhibitor A366. In an effort to improve the activity and explore the structure–activity relationship (SAR), a series of 21 derivatives was synthesized, tested in vitro, and investigated by means of molecular modeling tools. Docking studies and molecular dynamics (MD) simulations were performed to analyze and rationalize the structural differences responsible for the Spindlin1 activity. The analysis of MD simulations shed light on the important interactions. Our study highlighted the main structural features that are required for Spindlin1 inhibitory activity, which include a positively charged pyrrolidine moiety embedded into the aromatic cage connected via a propyloxy linker to the 2-aminoindole core. Of the latter, the amidine group anchor the compounds into the pocket through salt bridge interactions with Asp184. Different protocols were tested to identify a fast in silico method that could help to discriminate between active and inactive compounds within the A366 series. Rescoring the docking poses with MM-GBSA calculations was successful in this regard. Because A366 is known to be a G9a inhibitor, the most active developed Spindlin1 inhibitors were also tested over G9a and GLP to verify the selectivity profile of the A366 analogs. This resulted in the discovery of diverse selective compounds, among which 1s and 1t showed Spindlin1 activity in the nanomolar range and selectivity over G9a and GLP. Finally, future design hypotheses were suggested based on our findings.

Highlights

Spindlin1 is a chromatin reader protein that plays an important role in epigenetic regulation through the recognition and interpretation of histone modifications
Through in silico studies coupled with in vitro testing, we identified novel Spindlin1 inhibitors active in the low μM range; as an example, compound Robaa-1k is illustrated in Figure 1 [29]
In order to explore the structure–activity relationship (SAR) of A366 and to develop modified analogs, a congeneric (SAR), a congeneric series containing 21 A366 derivatives was synthesized and tested series was synthesized and tested. This led to the generation of a dataset consisting of 21 in vitro for their inhibitory activity against Spindlin1

Summary

Introduction

Spindlin is a chromatin reader protein that plays an important role in epigenetic regulation through the recognition and interpretation of histone modifications. It consists of three Tudor domains, with the second domain binding to the H3K4me (H3 trimethylated at lysine 4) mark [1,2,3]. Its interaction with H4K20me (H4 trimethylated at lysine 20) was described [4,5]. Since the binding of the latter histone mark displayed a weaker affinity than that of H3K4me, it has been hypothesized that the. H4K20me mark acts as a secondary binding partner for Spindlin1 [5]. The H3K4me3R8me2a methylation pattern increases the affinity of H3K4me, whereas

Methods

Results

Conclusion