Specificity of Watson–Crick Base Pairing on a Solid Surface Studied at the Atomic Scale

Otero, Roberto; Xu, Wei; Lukas, Maya; Kelly, Ross E. A.; Lægsgaard, Erik; Stensgaard, I.; Kjems, Jørgen; Kantorovich, Lev; Besenbacher, Flemming

doi:10.1002/anie.200803333

Cited by 74 publications

(76 citation statements)

References 37 publications

(40 reference statements)

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“…It is reasonable to expect that higher efficiency and accuracy in the molecular recognition process exist between the biomimetically modified nucleobases compared to the nucleobases C and G alone, because fewer competitive hydrogen-bonded configurations are available for the modified nucleobases. This is indeed confirmed by our previous experiments [8] performed with the unmodified bases C and G, where we found that Watson-Crick G-C pairs were only randomly embedded into a C filament and characteristic fivefold ring structures without higher ordering. In summary, we have demonstrated that Watson-Crick hydrogen bonding can indeed play a vital role in driving natural molecular recognition between complementary nucleobases on a noble gold surface, even under well-controlled UHV conditions.…”

supporting

confidence: 88%

“…In support of this postulation, molecular recognition between complementary bases, most likely driven by hydrogen bonding alone, has already been observed both at the liquid/solid (HOPG) interface and on the noble Au(111) surface under extreme ultrahigh vacuum (UHV) conditions. [8][9][10] These previous experiments were, however, conducted with nucleobases alone, and hence did not take the presence of deoxyribose into account. It is therefore of utmost importance to explore the role that Watson-Crick hydrogen bonding plays at surfaces in chemical structures that mimic nucleotides so as to address the fundamental question of how the polymerization of nucleotides may have started in the prebiotic soup in the absence of enzymes.…”

mentioning

confidence: 99%

“…Adsorption of such chemically modified nucleobases on a noble Au(111) surface under well-controlled UHV conditions constitutes an interesting model system that may give unique insight into the fundamental driving forces behind molecular recognition between complementary nucleobases. The Au-(111) surface served as a template to ensure that the nucleobases adopt a flat adsorption geometry [8,[18][19][20][21][22] that mimics the base-stacking situation in natural double-stranded nucleic acids (see the Supporting Information), and the wellcontrolled ultraclean UHV conditions provide an idealized environment without water, salts, metal ions, etc. The main determinants for intermolecular interactions between the nucleobases under these extreme conditions are limited to hydrogen bonding and possible van der Waals interactions between the aryl groups.…”

mentioning

confidence: 99%

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Supramolecular Porous Network Formed by Molecular Recognition between Chemically Modified Nucleobases Guanine and Cytosine

Wang

Jacobsen

et al. 2010

Angew Chem Int Ed

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supporting

confidence: 88%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Supramolecular Porous Network Formed by Molecular Recognition between Chemically Modified Nucleobases Guanine and Cytosine

Wang

Jacobsen

et al. 2010

Angew Chem Int Ed

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“…However, in many cases, e.g. for DNA bases 8,11,12,14,16 and melamine molecules on the Au(111) surface, 15,28 perylene-3,4,9,10-tetracarboxylic-3,4,9,10-dianhydride (PTCDA) molecules on the Ag(111) surface, 19,22,23 benzene 26 and PTCDA 30 molecules on the Au(111), Cu(111) and Ag(111) surfaces the calculated adsorption energies are too small (of the order of 0.1-0.2 eV) which is inconsistent with experimental observations of the desorption temperatures for these molecules (around 100-300 1C). This failure of standard generalized gradient approximation (GGA) functionals, such as e.g.…”

Section: Theoretical Background and Motivationmentioning

confidence: 99%

Role of van der Waals interaction in forming molecule-metal junctions: flat organic molecules on the Au(111) surface

Mura

Guļāns

Thonhauser

et al. 2010

Phys. Chem. Chem. Phys.

115

147

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The self-assembly of flat organic molecules on metal surfaces is controlled, apart from the kinetic factors, by the interplay between the molecule-molecule and molecule-surface interactions. These are typically calculated using standard density functional theory within the generalized gradient approximation, which significantly underestimates nonlocal correlations, i.e. van der Waals (vdW) contributions, and thus affects interactions between molecules and the metal surface in the junction. In this paper we address this question systematically for the Au(111) surface and a number of popular flat organic molecules which form directional hydrogen bonds with each other. This is done using the recently developed first-principles vdW-DF method which takes into account the nonlocal nature of electron correlation [M. Dion et al., Phys. Rev. Lett. 2004, 92, 246401]. We report here a systematic study of such systems involving completely self-consistent vdW-DF calculations with full geometry relaxation. We find that the hydrogen bonding between the molecules is only insignificantly affected by the vdW contribution, both in the gas phase and on the gold surface. However, the adsorption energies of these molecules on the surface increase dramatically as compared with the ordinary density functional (within the generalized gradient approximation, GGA) calculations, in agreement with available experimental data and previous calculations performed within approximate or semiempirical models, and this is entirely due to the vdW contribution which provides the main binding mechanism. We also stress the importance of self-consistency in calculating the binding energy by the vdW-DF method since the results of non-self-consistent calculations in some cases may be off by up to 20%. Our calculations still support the usually made assumption of the molecule-surface interaction changing little laterally suggesting that single molecules and their small clusters should be quite mobile at room temperature on the surface. These findings support a gas-phase modeling for some flat metal surfaces, such as Au(111), and flat molecules, at least as a first approximation.

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“…21,22 Molecular size and geometry, as well as interaction between molecules, are some of the key parameters determining whether or not molecular self-assembly is possible and what the final outcome will be. For instance, it has been shown that the mixture of adenine and cytosine, both DNA bases, does not lead to the formation of ordered multicomponent structures, 23 whereas several multicomponent structures have been obtained using semiconducting perylene-3,4,9,10-tetracarboxylic-3,4,9,10-dianhydride (PTCDA) molecules mixed pentacene 24 and 2,4,6-triamino-1,3,5-triazine, sym-triaminotriazine. 25 In this paper, we investigate the self-assembly of a nonsymmetric adenine DNA base ( Figure 1a) mixed with symmetric PTCDA molecules (Figure 1b) on a Au(111)-(22 Â √ 3) surface at room temperature in ultrahigh vacuum.…”

Section: ' Introductionmentioning

confidence: 99%

Fabrication of a Complex Two-Dimensional Adenine–Perylene-3,4,9,10-tetracarboxylic Dianhydride Chiral Nanoarchitecture through Molecular Self-Assembly

Sun¹,

Mura

Jonkman³

et al. 2012

J. Phys. Chem. C

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Tailoring complex organic nanoarchitectures is the focus of recent research interest for developing novel nanostructured materials. 1À5 Two-dimensional (2D) molecular nanoarchitectures can be engineered taking advantage of molecular self-assembly. 6À10 These structures can be tailored at the nanometer scale by exploiting intermolecular interactions. Molecules forming hydrogen bonds (H-bonds) are particularly interesting building blocks for creating sophisticated organic architectures 11À14 due to the high selectivity and directionality of these bindings. Various single 15,16 and multicomponent 17À19 H-bonded structures have been created using semiconducting as well as biomolecules. 20 Engineering new molecular bioarchitectures is especially appealing for developing new advanced drug delivery devices and sensors. Engineering multicomponent biomaterials via attaching one molecule to another requires a deep understanding of molecular interactions. Molecular building blocks have to be chemically and structurally compatible to form specific structures. Over the past decade, remarkable progress has been achieved in building on crystal surface molecular assemblies. This has been largely based on a "drop and see" approach (i.e., molecular adsorption followed by molecular arrangement characterization) rather than on the understanding of the underlying processes and interactions. It is widely believed that a more intelligent approach is now required which would allow "design" or "dial" of a structure with specific properties. 21,22 Molecular size and geometry, as well as interaction between molecules, are some of the key parameters determining whether or not molecular self-assembly is possible and what the final outcome will be. For instance, it has been shown that the mixture of adenine and cytosine, both DNA bases, does not lead to the formation of ordered multicomponent structures, 23 whereas several multicomponent structures have been obtained using semiconducting perylene-3,4,9,10-tetracarboxylic-3,4,9,10-dianhydride (PTCDA) molecules mixed pentacene 24 and 2,4,6-triamino-1,3,5-triazine, sym-triaminotriazine. 25 In this paper, we investigate the self-assembly of a nonsymmetric adenine DNA base ( Figure 1a) mixed with symmetric PTCDA molecules ( Figure 1b) on a Au(111)-(22 Â √ 3) surface at room temperature in ultrahigh vacuum. We observed using scanning tunneling microscopy (STM) that the molecules form a complex bicomponent chiral supramolecular network. The unit cell of the 2D PTCDAÀadenine architecture is composed of 14 molecules. The high stability of this architecture relies on PTCDAÀPTCDA and PTCDAÀadenine hydrogen bonding. Density functional theory (DFT) modeling reveals that the PTCDA-based skeleton of this complex nanoarchitecture is stabilized further by the adenine molecules which may take several orientations within the unit cell, rendering the whole monolayer to be adenine-disordered. ' EXPERIMENTAL SECTIONThe substrates were Au(111) films grown on mica. The samples were introduced into the ultrahigh ...

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Specificity of Watson–Crick Base Pairing on a Solid Surface Studied at the Atomic Scale

Cited by 74 publications

References 37 publications

Supramolecular Porous Network Formed by Molecular Recognition between Chemically Modified Nucleobases Guanine and Cytosine

Supramolecular Porous Network Formed by Molecular Recognition between Chemically Modified Nucleobases Guanine and Cytosine

Role of van der Waals interaction in forming molecule-metal junctions: flat organic molecules on the Au(111) surface

Fabrication of a Complex Two-Dimensional Adenine–Perylene-3,4,9,10-tetracarboxylic Dianhydride Chiral Nanoarchitecture through Molecular Self-Assembly

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