StACKER, A TOOL FOR SYSTEMS LEVEL ANALYSIS OF BASE STACKING IN NUCLEOTIDE-RICH STRUCTURES

Nucleic acid macromolecules can undergo significant structural changes—often mediated by nucleotide modification or molecular interactions. These alterations can be critical to their function. An ongoing challenge is to develop useful tools to quantify system-wide changes in nucleic acid-rich structures. We introduce StACKER, a robust Python package for observing conformational changes in a nucleic acid structure through its pi-stacking of base rings. StACKER creates System Stacking Fingerprints (SSFs) which highlight the landscape of pi-stacking throughout a molecule and can be used to show widespread conformational adjustments. Additionally, StACKER’s Pairwise Stacking Fingerprint (PSF) can further characterize pi-stacking in a select residue pair, showing how the effects of localized residue changes spread through a nucleic acid system. We apply StACKER to molecular dynamics (MD) simulations of a subsystem of the ribosome to reveal that alternative codons at the ribosome A-site and 3’ adjacent +1 codon position induce allosteric structure changes in the decoding center neighborhood, leading to a toggle between two conformational states. Through previous analysis of ribosome profiling data, we link these states to an observed fast/slow translation phenotype (Sun et al. 2024). We benchmark StACKER alongside other lenses for observing allostery to demonstrate its use in assessing allosteric shifts and its relevance to future structure-to-function studies.