Search results for "Immobilized Nucleic Acids"

showing 4 items of 4 documents

A Protein-Interaction Array Inside a Living Cell

2013

Cell phenotype is determined by protein network states that are maintained by the dynamics of multiple protein interactions.1 Fluorescence microscopy approaches that measure protein interactions in individual cells, such as by Forster resonant energy transfer (FRET), are limited by the spectral separation of fluorophores and thus are most suitable to analyze a single protein interaction in a given cell. However, analysis of correlations between multiple protein interactions is required to uncover the interdependence of protein reactions in dynamic signal networks. Available protein-array technologies enable the parallel analysis of interacting proteins from cell extracts, however, they can …

ImmunoprecipitationRecombinant Fusion Proteinsprotein-protein interactionsImmobilized Nucleic AcidsProtein Array AnalysisreceptorsDNA Single-StrandedCatalysisProtein–protein interactionReceptors G-Protein-CoupledBimolecular fluorescence complementationProtein Array AnalysisChlorocebus aethiopsFluorescence microscopeFluorescence Resonance Energy TransferAnimalsProtein Interaction MapsProtein kinase Amultiplexed assayChemistryProteinsProtein-protein interactions Dip Pen Nanolithography Protein KinaseDNA directed immobilizationGeneral MedicineGeneral ChemistryCommunicationssurface-immobilizationKineticsLuminescent ProteinsFörster resonance energy transferBiochemistryMicroscopy FluorescenceCOS CellsBiophysicsSignal transductionAntibodies Immobilizedsignal transduction
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Dielectrophoretic trapping of multilayer DNA origami nanostructures and DNA origami-induced local destruction of silicon dioxide

2015

DNA origami is a widely used method for fabrication of custom-shaped nanostructures. However, to utilize such structures, one needs to controllably position them on nanoscale. Here we demonstrate how different types of 3D scaffolded multilayer origamis can be accurately anchored to lithographically fabricated nanoelectrodes on a silicon dioxide substrate by DEP. Straight brick-like origami structures, constructed both in square (SQL) and honeycomb lattices, as well as curved "C"-shaped and angular "L"-shaped origamis were trapped with nanoscale precision and single-structure accuracy. We show that the positioning and immobilization of all these structures can be realized with or without thi…

ElectrophoresisMaterials scienceNanostructureSilicon dioxideta221educationClinical BiochemistryImmobilized Nucleic AcidsNanotechnology02 engineering and technologyDNA nanostructuresSubstrate (electronics)Microscopy Atomic Force01 natural sciencesBiochemistryAnalytical Chemistrychemistry.chemical_compoundHoneycombNanotechnologyDNA origamiDNA nanotechnologynanomanipulationElectrical measurementsSulfhydryl CompoundsElectrodesta218dielectrophoresista214ta114Physics010401 analytical chemistryElectric ConductivityDNAEquipment DesignDielectrophoresis021001 nanoscience & nanotechnologySilicon Dioxide0104 chemical sciencesNanostructuresChemistryNanolithographychemistryElectrical engineeringelectrical propertiesnanofabricationGold0210 nano-technologyBiotechnologyELECTROPHORESIS
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A DNA-nanoparticle actuator enabling optical monitoring of nanoscale movements induced by an electric field.

2018

Merging biological and non-biological matter to fabricate nanoscale assemblies with controllable motion and function is of great interest due to its potential application, for example, in diagnostics and biosensing. Here, we have constructed a DNA-based bionanoactuator that interfaces with biological and non-biological matter via an electric field in a reversibly controllable fashion. The read-out of the actuator is based on motion-induced changes in the plasmon resonance of a gold nanoparticle immobilized to a gold surface by single stranded DNA. The motion of the gold nanoparticle and thus the conformational changes of the DNA under varying electric field were analyzed by dark field spect…

Materials scienceta221Immobilized Nucleic AcidsPhysics::OpticsNanoparticleDNA Single-StrandedMetal NanoparticlesNanotechnology02 engineering and technology010402 general chemistrySpectrum Analysis Raman01 natural sciencesnanobiotechnologyBiokemia solu- ja molekyylibiologia - Biochemistry cell and molecular biologyNanoteknologia - NanotechnologyElectricityElectric fieldGeneral Materials ScienceBiotinylationSurface plasmon resonanceSpectroscopyQuantitative Biology::Biomoleculesta114Optical ImagingnanobiotekniikkaDNASurface Plasmon Resonance021001 nanoscience & nanotechnologyAvidin0104 chemical sciencesNanostructuresColloidal goldNucleic Acid ConformationnanohiukkasetnanoparticlesGold0210 nano-technologyActuatorBiosensorVoltageNanoscale
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Surface-immobilized DNAzyme-type biocatalysis

2014

The structure of the double helix of deoxyribonucleic acid (DNA, also called duplex-DNA) was elucidated sixty years ago by Watson, Crick, Wilkins and Franklin. Since then, DNA has continued to hold a fascination for researchers in diverse fields including medicine and nanobiotechnology. Nature has indeed excelled in diversifying the use of DNA: beyond its canonical role of repository of genetic information, DNA could also act as a nanofactory able to perform some complex catalytic tasks in an enzyme-mimicking manner. The catalytic capability of DNA was termed DNAzyme; in this context, a peculiar DNA structure, a quadruple helix also named quadruplex-DNA, has recently garnered considerable i…

StreptavidinSurface PropertiesImmobilized Nucleic AcidsDeoxyribozymeContext (language use)Nanotechnology010402 general chemistryG-quadruplex01 natural sciences[ CHIM ] Chemical Scienceschemistry.chemical_compoundNanobiotechnology[CHIM]Chemical Sciencesheterocyclic compoundsGeneral Materials ScienceComputingMilieux_MISCELLANEOUS010405 organic chemistryDNA Catalytic[CHIM.CATA]Chemical Sciences/Catalysis0104 chemical sciencesG-QuadruplexesPeroxidaseschemistryBiotinylationHelixBiocatalysisOxidation-ReductionDNA
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