First, DNA double-helical tiles with increasing flexibility were designed to investigate the dimerization kinetics. The higher dimerization rates of more rigid tiles result from the opposing effects of higher activation energies and higher pre-exponential factors from the Arrhenius equation, where the pre-exponential factor dominates. Next, the thermodynamics and kinetics of single tile attachment to preformed “multitile” arrays were investigated to test the fundamental assumptions of tile assembly models. The results offer experimental evidences that double crossover tile attachment is determined by the electrostatic environment and the steric hindrance at the binding site. Finally, the assembly of double crossover tiles within a rhombic DNA origami frame was employed as the model system to investigate the competition between unseeded, facet and seeded nucleation. The results revealed that preference of nucleation types can be tuned by controlling the rate-limiting nucleation step.
The works presented in this dissertation will be helpful for refining the DNA tile assembly model for future designs and simulations. Moreover, The works presented here could also be helpful in understanding how individual molecules interact and more complex cooperative bindings in chemistry and biology. The future direction will focus on the characterization of tile assembly at single molecule level and the development of error-free tile assembly systems.
DNA nanostructures of high programmability and complexity provide excellent scaffolds to arrange multiple molecular/macromolecular components at nanometer scale to construct interactive biomolecular complexes and networks. Due to the sequence specificity at different positions of the DNA origami nanostructures, spatially addressable molecular pegboard with a resolution of several nm (less than 10 nm) can be achieved. So far, DNA nanostructures can be used to build nanodevices ranging from in vitro small molecule biosensing to sophisticated in vivo therapeutic drug delivery systems and multi-enzyme networks.
This thesis focuses on how to use DNA nanostructures as programmable biomolecular scaffolds to arranges enzymatic systems. Presented here are a series of studies toward this goal. First, we survey approaches used to generate protein-DNA conjugates and the use of structural DNA nanotechnology to engineer rationally designed nanostructures. Second, novel strategies for positioning enzymes on DNA nanoscaffolds has been developed and optimized, including site-specific/ non site-specific protein-DNA conjugation, purification and characterization. Third, an artificial swinging arm enzyme-DNA complex has been developed to mimic substrate channeling process. Finally, we extended to build a artificial 2D multi-enzyme network.
DNA nanotechnology, the self-assembly of DNA into 2D and 3D nanoscale structures facilitated via Watson and Crick base pairing, provides alternative solutions for biomedical challenges, especially for therapeutic cargo delivery, because it is easily fabricated, exhibits low cytotoxicity, and high biocompatibility. However, the stability of these DNA nanostructures (DN) under cellular environment presents an issue due to their requirements for high salt conditions and susceptibility to nuclease degradation. Furthermore, DNs are typically trapped in endolysosomal compartments rather than the cytosol, where most of their cargo must be delivered. Many attempts to mitigate the stability issue have been made in recent years. Previously, our lab designed an endosomal escape peptide, Aurein 1.2 (denoted “EE, for endosomal escape)”, combined with a decalysine sequence (K10) proven to electrostatically adhere to and protect DNs under cell culture conditions. Unfortunately, this molecule, termed K10-EE, only resulted in endosomal escape in absence of serum due to formation of a protein corona on the surface of the coated DN.6 Therefore, we now propose to electrostatically coat the DN with a polymer composed of decalysine (K10), polyethylene glycol (PEG, which demonstrates antibiofouling properties), and peptide EE: K10- PEG1k-EE. Described herein are the attempted synthetic schemes of K10-PEG1k-EE, the successful synthesis of alternative products, K10-(EK)5 and K10-(PEG12)2-EE, and their resulting impacts on DN stability under biological conditions. Coating of the K10-(EK)5 with a DNA barrel origami demonstrated inefficient stabilizing capability in serum. Future studies include testing K10- (PEG12)2-EE protection for a variety of nucleic acid-based structures.
Eradication of multidrug-resistant bacteria using biomolecule-encapsulated two-dimensional materials
The x-ray crystallography structure of the β clamp suggests that there are oppositely charged amino acid pairs present at the interface of the dimer. They can form strong electrostatic interactions between them. However, for Proliferation Cell Nuclear Antigen (PCNA), there are no such charged amino acids present at its interface. High sodium chloride (NaCl) concentrations were used to disrupt the electrostatic interactions at the interface. The role of charged pairs in the clamp interface was characterized by measuring the apparent diffusion times (\tau_{app}) with fluorescence correlation spectroscopy (FCS). However, the dissociation of the Proliferation Cell Nuclear Antigen (PCNA) trimer does not depend on sodium chloride (NaCl) concentration.
In the next part of my thesis, potassium glutamate (KGlu) and glycine betaine (GB) were used to investigate their effect on the stability of both clamp proteins. FCS experiments with labeled β clamp and Proliferation Cell Nuclear Antigen (PCNA) were performed containing different concentrations of potassium glutamate and glycine betaine in the solution, showed that the apparent diffusion time\ {(\tau}_{app}) increases with potassium glutamate and glycine betaine concentrations, which indicate clamps are forming higher-order oligomers. Solute molecules get excluded from the protein surface when the binding affinity of the protein surface for water molecules is more than solutes (potassium glutamate, and glycine betaine), which has a net stabilizing effect on the protein structure.