Left Versus Right: Exploring the Effects of Chiral Threading Intercalators Using Optical Tweezers

Overview

Journal Biophys J

Publisher Cell Press

Specialty Biophysics

Date 2022 Apr 26

PMID 35470110

Authors

Adam A Jabak

Nicholas Bryden

Fredrik Westerlund

Per Lincoln

Micah J McCauley

Ioulia Rouzina

Mark C Williams

Thayaparan Paramanathan

Affiliations

Soon will be listed here.

Abstract

Small-molecule DNA-binding drugs have shown promising results in clinical use against many types of cancer. Understanding the molecular mechanisms of DNA binding for such small molecules can be critical in advancing future drug designs. We have been exploring the interactions of ruthenium-based small molecules and their DNA-binding properties that are highly relevant in the development of novel metal-based drugs. Previously we have studied the effects of the right-handed binuclear ruthenium threading intercalator ΔΔ-[μ-bidppz(phen)Ru], or ΔΔ-P for short, which showed extremely slow kinetics and high-affinity binding to DNA. Here we investigate the left-handed enantiomer ΛΛ-[μ-bidppz(phen)Ru], or ΛΛ-P for short, to study the effects of chirality on DNA threading intercalation. We employ single-molecule optical trapping experiments to understand the molecular mechanisms and nanoscale structural changes that occur during DNA binding and unbinding as well as the association and dissociation rates. Despite the similar threading intercalation binding mode of the two enantiomers, our data show that the left-handed ΛΛ-P complex requires increased lengthening of the DNA to thread, and it extends the DNA more than double the length at equilibrium compared with the right-handed ΔΔ-P. We also observed that the left-handed ΛΛ-P complex unthreads three times faster than ΔΔ-P. These results, along with a weaker binding affinity estimated for ΛΛ-P, suggest a preference in DNA binding to the chiral enantiomer having the same right-handed chirality as the DNA molecule, regardless of their common intercalating moiety. This comparison provides a better understanding of how chirality affects binding to DNA and may contribute to the development of enhanced potential cancer treatment drug designs.

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