Your search keyword '"Manoharan, Vinothan N."' showing total 8 results

1. Programming Directed Motion with DNA-Grafted Particles.

Author

Gehrels EW, Rogers WB, Zeravcic Z, and Manoharan VN

Subjects

Motion, Temperature, Colloids, DNA genetics

Abstract

Colloidal particles can be programmed to interact in complex ways by functionalizing them with DNA oligonucleotides. Adding DNA strand-displacement reactions to the system allows these interparticle interactions to respond to specific changes in temperature. We present the requirements for thermally driven directed motion of colloidal particles, and we explore how these conditions can be realized experimentally using strand-displacement reactions. To evaluate the concept, we build and test a colloidal "dancer": a single particle that can be driven to move through a programmed sequence of steps along a one-dimensional track composed of other particles. The results of these tests reveal the capabilities and limitations of using DNA-mediated interactions for applications in dynamic systems. Specifically, we discuss how to design the substrate to limit complexity while permitting full control of the motile component, how to ratchet the interactions to move over many substrate positions with a limited regime of control parameters, and how to use technological developments to reduce the probability of detachment without sacrificing speed.

Published

2022

2. Using DNA strand displacement to control interactions in DNA-grafted colloids.

Author

Gehrels EW, Rogers WB, and Manoharan VN

Subjects

Base Sequence, Colloids, DNA genetics, Models, Molecular, Nucleic Acid Conformation, Phase Transition, Thermodynamics, DNA chemistry

Abstract

Grafting DNA oligonucleotides to colloidal particles leads to specific, reversible interactions between those particles. However, the interaction strength varies steeply and monotonically with temperature, hindering the use of DNA-mediated interactions in self-assembly. We show how the dependence on temperature can be modified in a controlled way by incorporating DNA strand-displacement reactions. The method allows us to make multicomponent systems that can self-assemble over a wide range of temperatures, invert the dependence on temperature to design colloidal systems that melt upon cooling, controllably transition between structures with different compositions, or design systems with multiple melting transitions. This wide range of behaviors can be realized simply by adding a small number of DNA strands to the solution, making the approach modular and straightforward to implement. We conclude with practical considerations for designing systems of DNA-mediated colloidal interactions.

Published

2018

3. DNA nanotechnology. Programming colloidal phase transitions with DNA strand displacement.

Author

Rogers WB and Manoharan VN

Subjects

Colloids, Crystallization, Computers, Molecular, DNA chemistry, Information Theory, Nanoparticles chemistry, Phase Transition

Abstract

DNA-grafted nanoparticles have been called "programmable atom-equivalents": Like atoms, they form three-dimensional crystals, but unlike atoms, the particles themselves carry information (the sequences of the grafted strands) that can be used to "program" the equilibrium crystal structures. We show that the programmability of these colloids can be generalized to the full temperature-dependent phase diagram, not just the crystal structures themselves. We add information to the buffer in the form of soluble DNA strands designed to compete with the grafted strands through strand displacement. Using only two displacement reactions, we program phase behavior not found in atomic systems or other DNA-grafted colloids, including arbitrarily wide gas-solid coexistence, reentrant melting, and even reversible transitions between distinct crystal phases., (Copyright © 2015, American Association for the Advancement of Science.)

Published

2015

4. Tetrahedral colloidal clusters from random parking of bidisperse spheres.

Author

Schade NB, Holmes-Cerfon MC, Chen ER, Aronzon D, Collins JW, Fan JA, Capasso F, and Manoharan VN

Subjects

Computer Simulation, Static Electricity, Colloids chemistry, DNA chemistry, Models, Chemical

Abstract

Using experiments and simulations, we investigate the clusters that form when colloidal spheres stick irreversibly to--or "park" on--smaller spheres. We use either oppositely charged particles or particles labeled with complementary DNA sequences, and we vary the ratio α of large to small sphere radii. Once bound, the large spheres cannot rearrange, and thus the clusters do not form dense or symmetric packings. Nevertheless, this stochastic aggregation process yields a remarkably narrow distribution of clusters with nearly 90% tetrahedra at α = 2.45. The high yield of tetrahedra, which reaches 100% in simulations at α = 2.41, arises not simply because of packing constraints, but also because of the existence of a long-time lower bound that we call the "minimum parking" number. We derive this lower bound from solutions to the classic mathematical problem of spherical covering, and we show that there is a critical size ratio α(c) = (1 + sqrt[2]) ≈ 2.41, close to the observed point of maximum yield, where the lower bound equals the upper bound set by packing constraints. The emergence of a critical value in a random aggregation process offers a robust method to assemble uniform clusters for a variety of applications, including metamaterials.

Published

2013

5. DNA-enabled self-assembly of plasmonic nanoclusters.

Author

Fan JA, He Y, Bao K, Wu C, Bao J, Schade NB, Manoharan VN, Shvets G, Nordlander P, Liu DR, and Capasso F

Subjects

Electric Conductivity, Macromolecular Substances chemistry, Materials Testing, Molecular Conformation, Particle Size, Surface Properties, DNA chemistry, DNA ultrastructure, Nanostructures chemistry, Nanostructures ultrastructure, Surface Plasmon Resonance methods

Abstract

DNA nanotechnology provides a versatile foundation for the chemical assembly of nanostructures. Plasmonic nanoparticle assemblies are of particular interest because they can be tailored to exhibit a broad range of electromagnetic phenomena. In this Letter, we report the assembly of DNA-functionalized nanoparticles into heteropentamer clusters, which consist of a smaller gold sphere surrounded by a ring of four larger spheres. Magnetic and Fano-like resonances are observed in individual clusters. The DNA plays a dual role: it selectively assembles the clusters in solution and functions as an insulating spacer between the conductive nanoparticles. These particle assemblies can be generalized to a new class of DNA-enabled plasmonic heterostructures that comprise various active and passive materials and other forms of DNA scaffolding.

Published

2011

6. Programming colloidal phase transitions with DNA strand displacement.

Author

Rogers, W. Benjamin and Manoharan, Vinothan N.

Subjects

*NANOPARTICLES, *CRYSTAL structure, *COLLOIDS, *DNA, *PHASE transitions

Abstract

DNA-grafted nanoparticles have been called "programmable atom-equivalents": Like atoms, they form three-dimensional crystals, but unlike atoms, the particles themselves carry information (the sequences of the grafted strands) that can be used to "program" the equilibrium crystal structures. We show that the programmability of these colloids can be generalized to the full temperature-dependent phase diagram, not just the crystal structures themselves. We add information to the buffer in the form of soluble DNA strands designed to compete with the grafted strands through strand displacement. Using only two displacement reactions, we program phase behavior not found in atomic systems or other DNA-grafted colloids, including arbitrarily wide gas-solid coexistence, reentrant melting, and even reversible transitions between distinct crystal phases. [ABSTRACT FROM AUTHOR]

Published

2015

7. Dynamic Measurements of the Position, Orientation, and DNA Content of Individual Unlabeled Bacteriophages.

Author

Goldfain, Aaron M., Garmann, Rees F., Yan Jin, Lahini, Yoav, and Manoharan, Vinothan N.

Subjects

*BACTERIOPHAGES, *GENETIC transduction, *VIRULENCE of bacteriophages, *LYSOGENY, *DNA, *VIRUSES

Abstract

A complete understanding of the cellular pathways involved in viral infections will ultimately require a diverse arsenal of experimental techniques, including methods for tracking individual viruses and their interactions with the host. Here we demonstrate the use of holographic microscopy to track the position, orientation, and DNA content of unlabeled bacteriophages (phages) in solution near a planar, functionalized glass surface. We simultaneously track over 100 individual λ phages at a rate of 100 Hz across a 33 μm × 33 μm portion of the surface. The technique determines the in-plane motion of the phage to nanometer precision, and the height of the phage above the surface to 100 nm precision. Additionally, we track the DNA content of individual phages as they eject their genome following the addition of detergent-solubilized LamB receptor. The technique determines the fraction of DNA remaining in the phage to within 10% of the total 48.5 kilobase pairs. Analysis of the data reveals that under certain conditions, λ phages move along the surface with their heads down and intermittently stick to the surface by their tails, causing them to stand up. Furthermore, we find that in buffer containing high concentrations of both monovalent and divalent salts, λ phages eject their entire DNA in about 7 s. Taken together, these measurements highlight the potential of holographic microscopy to resolve the fast kinetics of the early stages of phage infection. [ABSTRACT FROM AUTHOR]

Published

2016

8. A Simple RNA-DNA Scaffold Templates the Assembly of Monofunctional Virus-Like Particles.

Author

Garmann, Rees F., Sportsman, Richard, Beren, Christian, Manoharan, Vinothan N., Knobler, Charles M., and Gelbart, William M.

Subjects

*VIRUS-like particles, *CAPSIDS, *DNA, *RNA viruses, *SYMMETRY (Physics)

Abstract

Using the components of a particularly well-studied plant virus, cowpea chlorotic mottle virus (CCMV), we demonstrate the synthesis of virus-like particles (VLPs) with one end of the packaged RNA extending out of the capsid and into the surrounding solution. This construct breaks the otherwise perfect symmetry of the capsid and provides a straightforward route for monofunctionalizing VLPs using the principles of DNA nanotechnology. It also allows physical manipulation of the packaged RNA, a previously inaccessible part of the viral architecture. Our synthesis does not involve covalent chemistry of any kind; rather, we trigger capsid assembly on a scaffold of viral RNA that is hybridized at one end to a complementary DNA strand. Interaction of CCMV capsid protein with this RNA-DNA template leads to selective packaging of the RNA portion into a well-formed capsid but leaves the hybridized portion poking out of the capsid through a small hole. We show that the nucleic acid protruding from the capsid is capable of binding free DNA strands and DNA-functionalized colloidal particles. Sepa rately, we show that the RNA-DNA scaffold can be used to nucleate virus formation on a DNA-functionalized surface. We believe this self-assembly strategy can be adapted to viruses other than CCMV. [ABSTRACT FROM AUTHOR]

Published

2015