Litcius/Paper detail

Rapid Computational Analysis of DNA Origami Assemblies at Near-Atomic Resolution

Jae Young Lee, Jae Gyung Lee, Giseok Yun, Chanseok Lee, Young‐Joo Kim, Kyung Soo Kim, Tae Hwi Kim, Do‐Nyun Kim

2021ACS Nano65 citationsDOIOpen Access PDF

Abstract

Structural DNA nanotechnology plays an ever-increasing role in advanced biomolecular applications. Here, we present a computational method to analyze structured DNA assemblies rapidly at near-atomic resolution. Both high computational efficiency and molecular-level accuracy are achieved by developing a multiscale analysis framework. The sequence-dependent relative geometry and mechanical properties of DNA motifs are characterized by the all-atom molecular dynamics simulation and incorporated into the structural finite element model successfully without significant loss of atomic information. The proposed method can predict the three-dimensional shape, equilibrium dynamic properties, and mechanical rigidities of monomeric to hierarchically assembled DNA structures at near-atomic resolution without adjusting any model parameters. The calculation takes less than only 15 min for most origami-scale DNA nanostructures consisting of 7000-8000 base-pairs. Hence, it is expected to be highly utilized in an iterative design-analysis-revision process for structured DNA assemblies.

Topics & Concepts

DNA origamiMolecular dynamicsResolution (logic)NanotechnologyDNANanostructureSequence (biology)Materials scienceBase pairFinite element methodDNA nanotechnologyBiological systemComputer scienceChemistryComputational chemistryPhysicsBiochemistryArtificial intelligenceBiologyThermodynamicsAdvanced biosensing and bioanalysis techniquesRNA Interference and Gene DeliveryBacteriophages and microbial interactions