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We report the anchoring of 3D-DNA-cholesterol labeled cages on spherically supported lipid bilayer membranes (SSLBM) formed on silica beads, and their addressability through strand displacement reactions, controlled membrane orientation and templated dimerization. The bilayer-anchored cages can load three different DNA-fluorophores by hybridization to their "top" face (furthest from bilayer) and unload each of them selectively upon addition of a specific input displacement strand. We introduce a method to control strand displacement from their less accessible "bottom" face (closest to the bilayer), by adding cholesterol-substituted displacing strands that insert into the bilayer themselves in order to access the toehold region. The orientation of DNA cages within the bilayer is tunable by positioning multiple cholesterol anchoring units on the opposing two faces of the cage, thereby controlling their accessibility to proteins and enzymes. A population of two distinct DNA cages anchored to the SSLBMs exhibited significant membrane fluidity and have been directed into dimer assemblies on bilayer via input of a complementary linking strand. Displacement experiments performed on these anchored dimers indicate that removal of only one prism's anchoring cholesterol strand was not sufficient to release the dimers from the bilayer; however, removal of both cholesterol anchors from the dimerized prisms via two displacement strands cleanly released the dimers from the bilayer. This methodology allows for the anchoring of DNA cages on supported lipid bilayers, the control of their orientation and accessibility within the bilayer, and the programmable dimerization and selective removal of any of their components. The facile coupling of DNA to other functional materials makes this an attractive method for developing stimuli-responsive protein or nanoparticle arrays, drug releasing biomedical device surfaces and self-healing materials for light harvesting applications, using a highly modular, DNA-economic scaffold.

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We measure the surface stress induced by electrochemical transformations of a thin conducting polymer film. One side of a micromechanical cantilever-based sensor is covered with an electropolymerized dodecyl benzenesulfonate-doped polypyrrole (PPyDBS) film. The microcantilever serves as both the working electrode (in a conventional three-electrode cell configuration) and as the mechanical transducer for simultaneous, in situ, and real-time measurements of the current and interfacial stress changes. A compressive change in surface stress of about -2 N/m is observed when the conducting polymer is electrochemically switched between its oxidized (PPy+) and neutral (PPy0) state by cyclic voltammetry. The surface stress sensor's response during the anomalous first reductive scan is examined. The effect of long-term cycling on the mechanical transformation ability of PPy(DBS) films in both surfactant and halide-based electrolytes is also discussed. We have identified two main competing origins of surface stress acting on the PPy(DBS)/ gold-coated microcantilever: one purely mechanical due to the volume change of the conducting polymer, and a second charge-induced, owing to the interaction of anions of the supporting electrolyte with the gold surface.

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The surface stress induced during the formation of alkanethiol self-assembled monolayers (SAMs) on gold from the vapor phase was measured using a micromechanical cantilever-based chemical sensor. Simultaneous in situ thickness measurements were carried out using ellipsometry. Ex situ scanning tunneling microscopy was performed in air to ascertain the final monolayer structure. The evolution of the surface stress induced during coverage-dependent structural phase transitions reveals features not apparent in average ellipsometric thickness measurements. These results show that both the kinetics of SAM formation and the resulting SAM structure are strongly influenced both by the surface structure of the underlying gold substrate and by the impingement rate of the alkanethiol onto the gold surface. In particular, the adsorption onto gold surfaces having large, flat grains produces high-quality self-assembled monolayers. An induced compressive surface stress of 15.9 +/- 0.6 N/m results when a c(4x2) dodecanethiol SAM forms on gold. However, the SAMs formed on small-grained gold are incomplete and an induced surface stress of only 0.51 +/- 0.02 N/m results. The progression to a fully formed SAM whose alkyl chains adopt a vertical (standing-up) orientation is clearly inhibited in the case of a small-grained gold substrate and is promoted in the case of a large-grained gold substrate.

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In this Account, we discuss the dynamic features of self-assembled monolayers (SAMs) on both planar and nonplanar substrates. Our focus is on organothiol and organic acid-based monolayers. Results from variable-temperature electrochemical, calorimetric, vibrational, and solid-state NMR spectroscopic measurements lead to a convergent description of SAM dynamics.

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Solid-state 2H NMR spectroscopy was used to study and characterize the conformation and order of bolaform lipid membranes. A series of 2H-labeled bolaform phosphatidylcholines has been synthesized and their properties compared to a [D4]dimyristoylphosphatidylcholine (DMPC) and a [D8]-32 macrocyclic phosphatidylcholine. 31P NMR measurements establish that the aqueous dispersions of these lipids adopt lamellar phases. Computational dePakeing was used to extract the spectrum of the oriented system from spectra consisting of a superposition of randomly oriented domains in an unoriented sample. A large (> 90 %) and constant value for the normalized segmental order parameter (Smol) was observed for all positions along the diacyl chain of the bolaform lipids and only a small population (< 10%) of a less ordered conformer was observed. The less ordered conformer is assigned to the looping conformation on the basis of comparison with the deuterated macrocyclic phospholipid which has an enforced loop in its diacyl chain. The predominant population(> 90%) of the bolaform lipids is assigned to a highly ordered, spanning conformer.

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The role of a flattened, relatively hydrophobic surface patch in the self-association of Chromatium vinosum HiPIP was assessed by substituting phenylalanine 48 with lysine. The reduction potential of the F48K variant was 26 mV higher than that of the wild-type (WT) recombinant (rc) HiPIP, consistent with the introduction of a positive charge close to the cluster. Nuclear magnetic resonance spectroscopy (NMR) revealed that the electronic structure of the oxidized cluster in these two proteins is very similar at 295 K. In contrast, the electron transfer self-exchange rate constant of F48K was at least 15-fold lower than that of the WT rcHiPIP, indicating that the introduction of a positive charge at position 48 diminishes self-association of the HiPIP in solution. Moreover, the substitution at position 48 abolished the fine structure in the g(z) region of the electron paramagnetic resonance (EPR) spectrum of oxidized C. vinosum rcHiPIP recorded in the presence of 1 M sodium chloride. These results support the hypothesis that the flattened, relatively hydrophobic patch mediates interaction between two molecules of HiPIP and that freezing-induced dimerization of the HiPIP mediated by this patch is responsible for the unusual fine structure observed in the EPR spectrum of the oxidized C. vinosum HiPIP.

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The kinetic properties of glucose oxidase (EC 1.1.3.4) which has been covalently immobilized to a rotating glassy carbon electrode surface have been investigated. Analysis of the rotation rate dependence of the hydrogen peroxide-derived current suggests that oxygen mass transport to the enzyme-electrode surface is rate controlling at low rotation rates. Only as the diffusion layer approaches zero thickness (i.e., infinitely fast rotation rate) does mass transport become unimportant. A diffusion-free glucose Km for air-saturated buffer is found to be 66 mM using this methodology. The importance of mass transport restrictions in two-substrate enzymes such as glucose oxidase is discussed in the context of biosensor design.

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