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1. Cooperative control of a DNA origami force sensor

   https://doi.org/10.1038/s41598-024-53841-3  

   Robbins, Ariel; Hildebolt, Hazen; Neuhoff, Michael; Beshay, Peter; Winter, Jessica O; Castro, Carlos E; Bundschuh, Ralf; Poirier, Michael G (December 2024, Scientific Reports)

   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. 

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2. Solvent Polarity Effects on the Mechanochemistry of Spiropyran Ring Opening

   https://doi.org/10.1021/jacs.3c11621  

   Lin, Yangju; Kouznetsova, Tatiana B; Foret, Alex G; Craig, Stephen L (February 2024, Journal of the American Chemical Society)

   The spiropyran mechanophore (SP) is employed as a reporter of molecular tension in a wide range of polymer matrices, but the influence of surrounding environment on the force-coupled kinetics of its ring opening has not been quantified. Here, we report single-molecule force spectroscopy studies of SP ring opening in five solvents that span normalized Reichardt solvent polarity factors (ETN) of 0.1–0.59. Individual multimechanophore polymers were activated under increasing tension at constant 300 nm s–1 displacement in an atomic force microscope. The extension results in a plateau in the force–extension curve, whose midpoint occurs at a transition force f* that corresponds to the force required to increase the rate constant of SP activation to approximately 30 s–1. More polar solvents lead to mechanochemical reactions that are easier to trigger; f* decreases across the series of solvents, from a high of 415 ± 13 pN in toluene to a low of 234 ± 9 pN in n-butanol. The trend in mechanochemical reactivity is consistent with the developing zwitterionic character on going from SP to the ring-opened merocyanine product. The force dependence of the rate constant (Δx‡) was calculated for all solvent cases and found to increase with ETN, which is interpreted to reflect a shift in the transition state to a later and more productlike position. The inferred shift in the transition state position is consistent with a double-well (two-step) reaction potential energy surface, in which the second step is rate determining, and the intermediate is more polar than the product. 

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3. Aptamer-based biotherapeutic conjugate for shear responsive release of Von Willebrand factor A1 domain

   https://doi.org/10.1039/D4NR02715A  

   Ismail, Esraa; Liu, Yi; Wang, Yi; Yazdanparast_Tafti, Sajedehalsadat; Zhang, X Frank; Cheng, Xuanhong (January 2025, Nanoscale)

   Smart polymers that mimic and even surpass the functionality of natural responsive materials have been actively researched. This study explores the design and characterization of a Single-MOlecule-based material REsponsive to Shear (SMORES) for the targeted release of A1, the platelet binding domain of the blood clotting protein von Willebrand factor (VWF). Each SMORES construct employs an aptamer molecule as the flow transducer and a microparticle to sense and amplify the hydrodynamic force. Within the construct, the aptamer, ARC1172, undergoes conformational changes beyond a shear stress threshold, mimicking the shear-responsive behavior of VWF. This conformational alteration modulates the bioavailability of its target, the VWF-A1 domain, ultimately releasing it at elevated shear. Through optical tweezer-based single-molecule force measurement, ARC1172s role as a force transducer was assessed by examining its unfolding under constant pulling force. We also investigated its refolding rate as a function of force under varied relaxation periods. These analyses revealed a narrow range of threshold forces (3–7 pN) governing the transition between folded and unfolded states. We subsequently constructed the SMORES material by conjugating ARC1172 and a microbead, and immobilizing the other end of the aptamer on a substrate. Single-molecule flow experiments on immobilized SMORES constructs revealed a peak A1 domain release within a flow rate range of (40–70 μL min−1). A COMSOL Multiphysics model translated these flow rates to total forces of 3.10 pN–5.63 pN experienced by the aptamers, aligning with single-molecule force microscopy predictions. Evaluation under variable flow conditions showed a peak binding of A1 to the platelet glycoprotein Ib (GPIB) within the same force range, confirming released payload functionality. Building on knowledge of aptamer biomechanics, this study presents a new strategy to create shear-stimulated biomaterials based on single biomolecules. 

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4. Control of the stepwise assembly–disassembly of DNA origami nanoclusters by pH stimuli-responsive DNA triplexes

   https://doi.org/10.1039/c9nr05047g  

   Yang, Shuo; Liu, Wenyan; Wang, Risheng (October 2019, Nanoscale)

   We present the pH-triggered reversible assembly of DNA origami clusters in a stepwise fashion. The structure formation and dissociation are controlled by a series of consecutive pH-stimulation processes that rely on the triplex-to-duplex transition of DNA triplexes in different pH conditions. This multilevel dynamic assembly strategy brings more structural complexity and provides the possibility of developing intelligent materials for engineering applications. 

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5. Structure‐Dependent Electrical Conductance of DNA Origami Nanowires

   https://doi.org/10.1002/cbic.202200454  

   Marrs, Jonathan; Lu, Qinyi; Pan, Victor; Ke, Yonggang; Hihath, Joshua (December 2022, ChemBioChem)

   Abstract Exploring the structural and electrical properties of DNA origami nanowires is an important endeavor for the advancement of DNA nanotechnology and DNA nanoelectronics. Highly conductive DNA origami nanowires are a desirable target for creating low‐cost self‐assembled nanoelectronic devices and circuits. In this work, the structure‐dependent electrical conductance of DNA origami nanowires is investigated. A silicon nitride (Si₃N₄) on silicon semiconductor chip with gold electrodes was used for collecting electrical conductance measurements of DNA origami nanowires, which are found to be an order of magnitude less electrically resistive on Si₃N₄substrates treated with a monolayer of hexamethyldisilazane (HMDS) (∼10¹³ohms) than on native Si₃N₄substrates without HMDS (∼10¹⁴ohms). Atomic force microscopy (AFM) measurements of the height of DNA origami nanowires on mica and Si₃N₄substrates reveal that DNA origami nanowires are ∼1.6 nm taller on HMDS‐treated substrates than on the untreated ones indicating that the DNA origami nanowires undergo increased structural deformation when deposited onto untreated substrates, causing a decrease in electrical conductivity. This study highlights the importance of understanding and controlling the interface conditions that affect the structure of DNA and thereby affect the electrical conductance of DNA origami nanowires. 

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