Self-assembled Materials Containing Complementary Nucleobase Molecular Recognition

Smitthipong, Wirasak; Chworoś, Arkadiusz; Lin, Bingyi; Neumann, Thorsten; Gajria, Surekha; Jaeger, Luc; Tirrell, Matthew

doi:10.1557/proc-1094-dd06-05

Cited by 4 publications

(8 citation statements)

References 10 publications

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“…Both supramolecular films, DNA-DDAB and PSS-DDAB at 30mm-thickness appear to be transparent. Based on comparison with previous works, [17][18][19] we found that in the multi-lamellar structure of the supramolecular film layers of the polyanion (DNA and presumably PSS) are separated by lipid bilayers of DDAB. The hydrophobic interactions among the double alkyl tails of DDAB molecules are probably responsible for the lipid bilayer formation within the film.…”

Section: Resultssupporting

confidence: 55%

“…The hydrophobic interactions among the double alkyl tails of DDAB molecules are probably responsible for the lipid bilayer formation within the film. [17][18][19][20] The contents of carbon, hydrogen and nitrogen in the film were determined by elemental analysis, which confirms that the obtained films were formed in a one to one stoichiometry of an anionic polymer and a cationic amphiphile: DNA-DDAB film C 58%, H 11% and N 8% (theoretical calculation C 56%, H 9% and N 9%) and PSS-DDAB film C 67%, H 11% and N 3% (theoretical calculation C 64%, H 10% and N 2%).…”

Section: Resultsmentioning

confidence: 99%

“…These results are in good agreement with previous work on the relationship of the double-stranded molecule with the elongation at the break point. 19 It should be noted that the stress-strain curve of the DNA-DDAB film resembles a typical cold drawing polymer, which gives rise to the late increase in stress after the initial yielding. 26 As evidenced in Fig.…”

Section: Resultsmentioning

confidence: 99%

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Supramolecular cooperative-assembly of polyelectrolyte films

2013

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In this report we investigate and compare the characteristics of the cooperative-assembly of doublestranded DNA and random coil poly(styrene sulfonate) mixed with didodecyldimethylammonium bromide (DDAB). Film formation is attributed primarily to electrostatic interactions between anionic phosphate or sulfonate groups (DNA or PSS) and cationic ammonium groups of DDAB. It appears that the elasticity and morphology of such films are dependent on the length and the structure of polymers. Ethidium bromide (a nucleic acid stain and intercalating agent) was employed to probe the structure of polymers based on the photoluminescence response of this dye.

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Section: Resultssupporting

confidence: 55%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Supramolecular cooperative-assembly of polyelectrolyte films

2013

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“…The recent synthesis of particle building blocks functionalized with specifically designed oligonucleotides has provided new possibilities for the assembly of networked materials. [1][2][3][4][5][6][7][8][9] The varied applications of polymer microspheres benefit from precise control over surface chemistry. Grafted molecules or functional groups determine the rheology 10 and stability of the colloids used in pastes and coatings, influence the self-organization of the dense suspensions used in materials synthesis, and provide specific biomolecular binding sites for biological assays and cell adhesion.…”

Section: Introductionmentioning

confidence: 99%

“…3,[18][19][20][21][22][23][24] Nucleic acids can also be used as a bulk material for a new type of biomaterial based on DNA/RNAsurfactant solid films. 4,5,25 General assembly methods for DNA are based on the use of covalent linker molecules which possess alkanedithiol functionalities at opposing ends with chemical affinities towards gold particles. 26,27 The thiol groups present at the end of the linker molecule are covalently attached to the gold colloidal particles and this facilitates aggregation upon binding to the complementary sequence.…”

Section: Introductionmentioning

confidence: 99%

Specific interaction of DNA-functionalized polymer colloids

2010

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As a chemically based assembly system, DNA is a key player for use in the reversible and specific interactions of an advanced material. In this approach, we work with a one-component system where a number of DNA single strands are grafted on the surface of micro-sized particles. The interactions between the DNA-functionalized particles are controlled by the addition of DNA linker in solution, which has complementary sequences with the DNA strands grafted on the particles. The hydrogen bonding based on Watson-Crick pairing is the driving force to form double stranded DNA. Several techniques have been used to characterize this system; for example, optical microscopy, AFM, DLS and flow cytometry. The two DNA strands reversibly separate (denature) above a characteristic melting temperature of DNA's base pair sequences. The melting temperature of DNA in the study is in good agreement with that of calculation based on the thermodynamic point of view.

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