Mechanically interlocked molecules such as rotaxanes and catenanes have potential as components of molecular machinery. Rotaxanes consist of a dumb-bell-shaped molecule encircled by a macrocycle that can move unhindered along the axle, trapped by bulky stoppers. Previously, rotaxanes have been made from a variety of molecules, but not from DNA. Here, we report the design, assembly and characterization of rotaxanes in which both the dumb-bell-shaped molecule and the macrocycle are made of double-stranded DNA, and in which the axle of the dumb-bell is threaded through the macrocycle by base pairing. The assembly involves the formation of pseudorotaxanes, in which the macrocycle and the axle are locked together by hybridization. Ligation of stopper modules to the axle leads to the characteristic dumb-bell topology. When an oligonucleotide is added to release the macrocycle from the axle, the pseudorotaxanes are either converted to mechanically stable rotaxanes, or they disassemble by means of a slippage mechanism to yield a dumb-bell and a free macrocycle. Our DNA rotaxanes allow the fields of mechanically interlocked molecules and DNA nanotechnology to be combined, thus opening new possibilities for research into molecular machines and synthetic biology.
Lone-pair...pi and, more recently, pi...pi interactions have been studied in small molecule crystal structures, and they are the focus of attention in some biomolecules. In this study, we have systematically analyzed 500 high-resolution protein structures (resolution < or =1.8 A) and identified 286 examples in which carbonyl oxygen atoms approach the aromatic centers within a distance of 3.5 A. Contacts involving backbone carbonyl oxygens are frequently observed in helices and, to some extent, in strands. Geometrical characterization indicates that these contacts have geometry in between that of an ideal pi...pi and a lone-pair...pi interaction. Quantum mechanical calculations using 6-311++G** basis sets reveal that these contacts give rise to energetically favorable interactions and, along with MD simulations, indicate that such interactions could stabilize secondary structures.
This communication describes formation of a 3N-coordinated silver-modified adenine metallamacrocyclic quartet in solid state, its aggregative ordering on graphite surface, and luminescence.
on a JEOL SX 102/DA-6000 mass spectrometer. Elemental (C, H, N) analyses were done on a Perkin Elmer 240-C automatic elemental analyzer.Synthesis of 9-allyladenine (9-AA): Experimental details for the synthesis of 9-AA have been reported earlier. 1 A similar protocol was followed and the purity of product so obtained was confirmed by spectroscopic analysis.
This Communication describes structures of a family of silver-adenine (purine) metallaquartets that occur in a four-stranded coordination motif, bearing a close resemblance to nucleic acid quadruplexes. Using modified purine frameworks, it is further demonstrated that subtle variations in nucleobase heterocycle are tolerable and a metallaquartet is obtained irrespective of the substitution, thus suggesting a high-propensity silver-adenine interaction to achieve quartet structures. All of the solid-state structures studied were orthorhombic, belonging to the Fdd2 space group.
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