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Replication of DNA Tetrahedron and Higher-order Self-assembly of DNA OrigamiJanuary 2012 (has links)
abstract: Deoxyribonucleic acid (DNA) has been treated as excellent building material for nanoscale construction because of its unique structural features. Its ability to self-assemble into predictable and addressable nanostructures distinguishes it from other materials. A large variety of DNA nanostructures have been constructed, providing scaffolds with nanometer precision to organize functional molecules. This dissertation focuses on developing biologically replicating DNA nanostructures to explore their biocompatibility for potential functions in cells, as well as studying the molecular behaviors of DNA origami tiles in higher-order self-assembly for constructing DNA nanostructures with large size and complexity. Presented here are a series of studies towards this goal. First, a single-stranded DNA tetrahedron was constructed and replicated in vivo with high efficiency and fidelity. This study indicated the compatibility between DNA nanostructures and biological systems, and suggested a feasible low-coast method to scale up the preparation of synthetic DNA. Next, the higher-order self-assembly of DNA origami tiles was systematically studied. It was demonstrated that the dimensional aspect ratio of origami tiles as well as the intertile connection design were essential in determining the assembled superstructures. Finally, the effects of DNA hairpin loops on the conformations of origami tiles as well as the higher-order assembled structures were demonstrated. The results would benefit the design and construction of large complex nanostructures. / Dissertation/Thesis / Ph.D. Biochemistry 2012
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Towards colloidal self-assembly for functional materialsRuff, Zachary January 2018 (has links)
Nanostructuring has led to materials with novel and improved materials properties driving innovation across fields as varied as transportation, computing, energy and biotechnology. However, the benefits of nanostructured material have not widely been extended into large-scale, three-dimensional applications as deterministic pattern techniques have proven too expensive for devices outside of high value products. This thesis explores how colloidal self-assembly can be used to form macroscopic functional materials with short-range order for electronic, photonic and electrochemical applications at scale. DNA-functionalized nanoparticles are versatile models for exploring colloidal self-assembly due to the highly specific, tunable and thermally reversible binding between DNA strands. Gold nanoparticles coated with DNA were used to investigate the temperature-dependent interaction potentials and the gel formation in DNA-colloidal systems. The electronic conductivity and the plasmonic response of the DNA-gold gels were studied to explore their applicability as porous electrodes and SERS substrates, respectively. Subsequently, silica nanoparticles were assembled into nanostructures that preferentially scatter blue light using both DNA and polymer-colloid interactions. Finally, rod-sphere structures made from DNA-coated gold nanoparticles and viruses were explored, demonstrating how high-aspect ratio building blocks can create composite structures with increased porosity. The gold-virus gel structures inspired the design and assembly of a silicon-carbon nanotube composite material using covalent bonds that shows promise for high energy density anodes.
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Enzymatic formation of supramolecular hydrogels based on self-assembly of DNA derivativesChen, Junpeng. January 2009 (has links)
Thesis (M.S.)--Brandeis University, 2009. / Title from PDF title page (viewed on August 9, 2009). Includes bibliographical references.
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Resonance Energy Transfer-Based Molecular Switch Designed Using a Systematic Design Process Based on Monte Carlo Methods and Markov ChainsRallapalli, Arjun January 2016 (has links)
<p>A RET network consists of a network of photo-active molecules called chromophores that can participate in inter-molecular energy transfer called resonance energy transfer (RET). RET networks are used in a variety of applications including cryptographic devices, storage systems, light harvesting complexes, biological sensors, and molecular rulers. In this dissertation, we focus on creating a RET device called closed-diffusive exciton valve (C-DEV) in which the input to output transfer function is controlled by an external energy source, similar to a semiconductor transistor like the MOSFET. Due to their biocompatibility, molecular devices like the C-DEVs can be used to introduce computing power in biological, organic, and aqueous environments such as living cells. Furthermore, the underlying physics in RET devices are stochastic in nature, making them suitable for stochastic computing in which true random distribution generation is critical.</p><p>In order to determine a valid configuration of chromophores for the C-DEV, we developed a systematic process based on user-guided design space pruning techniques and built-in simulation tools. We show that our C-DEV is 15x better than C-DEVs designed using ad hoc methods that rely on limited data from prior experiments. We also show ways in which the C-DEV can be improved further and how different varieties of C-DEVs can be combined to form more complex logic circuits. Moreover, the systematic design process can be used to search for valid chromophore network configurations for a variety of RET applications.</p><p>We also describe a feasibility study for a technique used to control the orientation of chromophores attached to DNA. Being able to control the orientation can expand the design space for RET networks because it provides another parameter to tune their collective behavior. While results showed limited control over orientation, the analysis required the development of a mathematical model that can be used to determine the distribution of dipoles in a given sample of chromophore constructs. The model can be used to evaluate the feasibility of other potential orientation control techniques.</p> / Dissertation
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Enzymatic Polymerization of High Molecular Weight DNATang, Lei January 2016 (has links)
<p>The use of DNA as a polymeric building material transcends its function in biology and is exciting in bionanotechnology for applications ranging from biosensing, to diagnostics, and to targeted drug delivery. These applications are enabled by DNA’s unique structural and chemical properties, embodied as a directional polyanion that exhibits molecular recognition capabilities. Hence, the efficient and precise synthesis of high molecular weight DNA materials has become key to advance DNA bionanotechnology. Current synthesis methods largely rely on either solid phase chemical synthesis or template-dependent polymerase amplification. The inherent step-by-step fashion of solid phase synthesis limits the length of the resulting DNA to typically less than 150 nucleotides. In contrast, polymerase based enzymatic synthesis methods (e.g., polymerase chain reaction) are not limited by product length, but require a DNA template to guide the synthesis. Furthermore, advanced DNA bionanotechnology requires tailorable structural and self-assembly properties. Current synthesis methods, however, often involve multiple conjugating reactions and extensive purification steps.</p><p>The research described in this dissertation aims to develop a facile method to synthesize high molecular weight, single stranded DNA (or polynucleotide) with versatile functionalities. We exploit the ability of a template-independent DNA polymerase−terminal deoxynucleotidyl transferase (TdT) to catalyze the polymerization of 2’-deoxyribonucleoside 5’-triphosphates (dNTP, monomer) from the 3’-hydroxyl group of an oligodeoxyribonucleotide (initiator). We termed this enzymatic synthesis method: TdT catalyzed enzymatic polymerization, or TcEP.</p><p>Specifically, this dissertation is structured to address three specific research aims. With the objective to generate high molecular weight polynucleotides, Specific Aim 1 studies the reaction kinetics of TcEP by investigating the polymerization of 2’-deoxythymidine 5’-triphosphates (monomer) from the 3’-hydroxyl group of oligodeoxyribothymidine (initiator) using in situ 1H NMR and fluorescent gel electrophoresis. We found that TcEP kinetics follows the “living” chain-growth polycondensation mechanism, and like in “living” polymerizations, the molecular weight of the final product is determined by the starting molar ratio of monomer to initiator. The distribution of the molecular weight is crucially influenced by the molar ratio of initiator to TdT. We developed a reaction kinetics model that allows us to quantitatively describe the reaction and predict the molecular weight of the reaction products.</p><p>Specific Aim 2 further explores TcEP’s ability to transcend homo-polynucleotide synthesis by varying the choices of initiators and monomers. We investigated the effects of initiator length and sequence on TcEP, and found that the minimum length of an effective initiator should be 10 nucleotides and that the formation of secondary structures close to the 3’-hydroxyl group can impede the polymerization reaction. We also demonstrated TcEP’s capacity to incorporate a wide range of unnatural dNTPs into the growing chain, such as, hydrophobic fluorescent dNTP and fluoro modified dNTP. By harnessing the encoded nucleotide sequence of an initiator and the chemical diversity of monomers, TcEP enables us to introduce molecular recognition capabilities and chemical functionalities on the 5’-terminus and 3’-terminus, respectively.</p><p>Building on TcEP’s synthesis capacities, in Specific Aim 3 we invented a two-step strategy to synthesize diblock amphiphilic polynucleotides, in which the first, hydrophilic block serves as a macro-initiator for the growth of the second block, comprised of natural and/or unnatural nucleotides. By tuning the hydrophilic length, we synthesized the amphiphilic diblock polynucleotides that can self-assemble into micellar structures ranging from star-like to crew-cut morphologies. The observed self-assembly behaviors agree with predictions from dissipative particle dynamics simulations as well as scaling law for polyelectrolyte block copolymers.</p><p>In summary, we developed an enzymatic synthesis method (i.e., TcEP) that enables the facile synthesis of high molecular weight polynucleotides with low polydispersity. Although we can control the nucleotide sequence only to a limited extent, TcEP offers a method to integrate an oligodeoxyribonucleotide with specific sequence at the 5’-terminus and to incorporate functional groups along the growing chains simultaneously. Additionally, we used TcEP to synthesize amphiphilic polynucleotides that display self-assemble ability. We anticipate that our facile synthesis method will not only advance molecular biology, but also invigorate materials science and bionanotechnology.</p> / Dissertation
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ENGINEERED 3D DNA CRYSTALS: CHARACTERIZATION, STABILIZATION AND APPLICATIONSZhe Li (6581093) 10 June 2019 (has links)
In recent years, DNA nanotechnology has emerged as one of the most
powerful strategies for bottom-up construction of nanomaterials. Due to
the high programmability of DNA molecules, their self-assembly can be
rationally designed. Engineered 3D DNA crystals, as critical products
from the design of DNA self-assembly, have been proposed as the
structural scaffolds for organizing nano-objects into three-dimensional,
macroscopic devices. However, for such applications, many obstacles
need to be overcome, including the crystal stability, the
characterization methodology, the revision of crystal designs as well as
the modulation of crystallization kinetics. My PhD research focuses on
solving these problems for engineered 3D DNA crystals to pave the way
for their downstream applications.<br>In this thesis, I started by
enhancing the stability of engineered 3D DNA crystals. I developed a
highly efficient post-assembly modification approach to stabilize DNA
crystals. Enzymatic ligation was performed inside the crystal lattice,
which was designed to covalently link the sticky ends at the crystal
contacts. After ligation, the crystal became a covalently bonded 3D
network of DNA motifs. I investigated the stability of ligated DNA
crystals under a wide range of solution conditions. Experimental data
revealed that ligated DNA crystals had significantly increased
stability. With these highly stabilized DNA crystals, we then
demonstrated their applications in biocatalysis and protein
encapsulation as examples.<br>I also established electron microscope
imaging characterization methods for engineered 3D DNA crystals. For
crystals from large-size DNA motifs, they are difficult to study by
X-ray crystallography because of their limited diffraction resolutions
to no better than 10 Å. Therefore, a direct imaging method by TEM was
set up. DNA crystals were either crushed or controlled to grow into
microcrystals for TEM imaging. To validate the imaging results, we
compared the TEM images with predicted models of the crystal lattice.
With the advance in crystal characterization, DNA crystals of varying
pore size between 5~20 nm were designed, assembled, and validated by TEM
imaging.<br>The post-assembly ligation was further developed to prepare
a series of new materials derived from engineered 3D DNA crystals,
which were inaccessible otherwise. With the directional and spatial
control of ligation in DNA crystal, I prepared new DNA-based materials
including DNA microtubes, complex-architecture crystals, and an
unprecedented reversibly expandable, self-healing DNA crystal. The
integration of weak and strong interactions in crystals enabled a lot of
new opportunities for DNA crystal engineering.<br>In the final chapter,
I investigated the effect of 5’-phosphorylation on DNA crystallization
kinetics. I found that phosphorylation significantly enhanced the
crystallization kinetics, possibly by strengthening the sticky-ended
cohesion. Therefore, DNA crystals can be obtained at much lower ionic
strength after phosphorylation. I also applied the result to controling
the morphology of DNA crystals by tuning the crystallization kinetics
along different crystallographic axes. Together with previously methods
to slow down DNA crystallization, the ability to tune DNA
crystallization kinetics in both ways is essential for DNA crystal
engineering.
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Rational-designed DNA Nanostructures And CrystalsMengxi Zheng (13120686) 20 July 2022 (has links)
<p> DNA origami is a powerful method to construct DNA nanostructures. It requires long, single-stranded DNAs. The preparation of such long DNA strands is often quite tedious and has a limited production yield. In contrast, duplex DNAs can be easily prepared via enzymatic reactions in large quantities. Thus, we ask a question: can we design DNA nanostructures in such a way that the two complementary strands can simultaneously fold into the designed structures in the same solution instead of hybridizing with each other to form a DNA duplex? By engineering DNA interaction kinetics, herein, we are able to provide multiple examples to concretely demonstrate a positive answer to this question. The resulting DNA nanostructures have been thoroughly characterized by electrophoresis and atomic force microscopy imaging. The reported strategy is compatible with the DNA cloning method; thus, would provide a convenient way for large-scale production of the designed DNA nanostructures. </p>
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Applying DNA Self-assembly in Formal Language TheoryAkkara, Pinto 14 October 2013 (has links)
No description available.
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Fabrication and Characterization of DNA Templated Electronic Nanomaterials and Their Directed Placement by Self-Assembly of Block CopolymersRanasinghe Weerakkodige, Dulashani Ruwanthika 01 August 2022 (has links)
Bottom-up self-assembly has the potential to fabricate nanostructures with advanced electrical features. DNA templates have been used to enable such self-assembling methods due to their versatility and compatibility with various nanomaterials. This dissertation describes research to advance several different steps of biotemplated nanofabrication, from DNA assembly to characterization. I assembled different nanomaterials including surfactant-coated Au nanorods, DNA-linked Au nanorods and Pd nanoparticles on DNA nanotubes ~10 micrometer long, and on ~400 nm long bar-shaped DNA origami templates. I optimized seeding by changing the surfactant and magnesium ion concentrations in the seeding solution. After successful seeding, I performed electroless plating on those nanostructures to fabricate continuous nanowires. Using the four-point probe technique, I performed resistivity measurements for Au nanowires on DNA nanotubes and obtained values between 9.3 x 10-6 and 1.2 x 10-3 ohm meter. Finally, I demonstrated the directed placement of DNA origami using block copolymer self-assembly. I created a gold nanodot array using block copolymer patterning and metal evaporation followed by lift-off. Then, I used different ligand groups and DNA hybridization to attach DNA origami to the nanodots. The DNA hybridization approach showed greater DNA attachment to Au nanodots than localization by electrostatic interaction. These results represent vital progress in understanding DNA-templated components, nanomaterials, and block copolymer nanolithography. The work in this dissertation shows potential for creating DNA-templated nanodevices and their placement in an ordered array in future nanoelectronics. Each of the described materials and techniques further has potential for addressing the need for increased complexity and integration for future applications.
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Active Tile Self-assembly and Simulations of Computational SystemsKarpenko, Daria 01 April 2015 (has links)
Algorithmic self-assembly has been an active area of research at the intersection of computer science, chemistry, and mathematics for almost two decades now, motivated by the natural self-assembly mechanism found in DNA and driven by the desire for precise control of nanoscale material manufacture and for the development of nanocomputing and nanorobotics. At the theoretical core of this research is the Abstract Tile Assembly Model (aTAM), the original abstract model of DNA tile self-assembly. Recent advancements in DNA nanotechnology have been made in developing strand displacement mechanisms that could allow DNA tiles to modify themselves during the assembly process by opening or closing certain binding sites, introducing new dynamics into tile self-assembly.
We focus on one way of incorporating such signaling mechanisms for binding site activation and deactivation into the theoretical model of tile self-assembly by extending the aTAM to create the Active aTAM. We give appropriate definitions first for incorporating activation signals and then for incorporating deactivation signals and tile detachment into the aTAM. We then give a comparison of Active aTAM to related models, such as the STAM, and take a look at some theoretical results.
The goal of the work presented here is to define and demonstrate the power of the Active aTAM with and without deactivation. To this end, we provide four constructions of temperature 1 (also known as "non-cooperative") active tile assembly systems that can simulate other computational systems. The first construction concerns the simulation of an arbitrary temperature 2 (also known as "cooperative") standard aTAM system in the sense of producing equivalent structures with a scaling factor of 2 in each dimension; the second construction generates the time history of a given 1D cellular automaton. The third and fourth constructions make use of tile detachment in order to dynamically simulate arbitrary 1D and 2D cellular automata with assemblies that record only the current state updates and not the entire computational history of the specified automaton.
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