Litcius/Paper detail

Cooperative control of a DNA origami force sensor

Ariel Robbins, Hazen Hildebolt, Michael Neuhoff, Peter E. Beshay, Jessica O. Winter, Carlos E. Castro, Ralf Bundschuh, Michael G. Poirier

2024Scientific Reports11 citationsDOIOpen Access PDF

Abstract

Biomolecular systems are dependent on a complex interplay of forces. Modern force spectroscopy techniques provide means of interrogating these forces, but they are not optimized for studies in constrained environments as they require attachment to micron-scale probes such as beads or cantilevers. Nanomechanical devices are a promising alternative, but this requires versatile designs that can be tuned to respond to a wide range of forces. We investigate the properties of a nanoscale force sensitive DNA origami device which is highly customizable in geometry, functionalization, and mechanical properties. The device, referred to as the NanoDyn, has a binary (open or closed) response to an applied force by undergoing a reversible structural transition. The transition force is tuned with minor alterations of 1 to 3 DNA oligonucleotides and spans tens of picoNewtons (pN). The DNA oligonucleotide design parameters also strongly influence the efficiency of resetting the initial state, with higher stability devices (≳10 pN) resetting more reliably during repeated force-loading cycles. Finally, we show the opening force is tunable in real time by adding a single DNA oligonucleotide. These results establish the potential of the NanoDyn as a versatile force sensor and provide fundamental insights into how design parameters modulate mechanical and dynamic properties.

Topics & Concepts

Force spectroscopyDNA origamiNanotechnologyCantileverNanoscopic scaleOligonucleotideMaterials scienceComputer scienceBiological systemDNAAtomic force microscopyChemistryNanostructureBiologyComposite materialBiochemistryAdvanced biosensing and bioanalysis techniquesRNA Interference and Gene DeliveryForce Microscopy Techniques and Applications