The mechanism of cavitation-induced scission of single-walled carbon nanotubes.

Aqueous suspensions of length selected single-walled carbon nanotubes were studied by atomic force microscopy (AFM) in order to probe the influence of sonication on nanotube scission. The maximum of the tube length distribution, lM, initially exhibits a power law dependence on the sonication time, t - roughly as lM approximately t(-0.5). This and the limiting behavior observed at longer times can be rationalized to first order in terms of a continuum model deriving from polymer physics. In this picture, the strain force associated with cavitation scales with the square of the nanotube length. Scission stops when the strain force falls below the critical value for nanotube disruption.

Tuning the reaction site for enzyme-free primer-extension reactions through small molecule substituents.

The replication of genetic information relies on the template-directed extension of DNA primers catalyzed by polymerases. The active sites of polymerases accept four different substrates and ensure fidelity and processivity for each of them. Because of the pivotal role of catalyzed primer extension for life, it is important to better understand this reaction on a molecular level. Here we present results from primer-extension reactions performed with chemical systems that show high reactivity in the absence of polymerases. Small molecular caps linked to the 5'-terminus of templates are shown to enhance the rate and selectivity of primer extension driven by 2-methylimidazolides as activated monomers for any of the four different templating bases (A, C, G, and T). The most consistent effect is provided by a stilbene carboxamide residue, rather than larger aromatic or aliphatic substituents. Up to 20-fold rate enhancements were achieved for the reactions at the terminus of the template. The preference for a medium size cap can be explained by competing interactions with both the oligonucleotides and the incoming deoxynucleotide. The data also show that there is no particularly intractable problem in combining promiscuity with fidelity. Exploratory experiments involving a longer template and a downstream-binding strand with a 5'-cap show up to 38-fold rate acceleration over the same reaction templated by a single overhanging nucleotide.

How much pi-stacking do DNA termini seek? Solution structure of a self-complementary DNA hexamer with trimethoxystilbenes capping the terminal base pairs.

The exposed terminal base pairs of DNA duplexes are nonclassical binding sites for small molecules. Instead, small molecules usually prefer intercalation or minor groove binding. Here we report the solution structure of the DNA duplex (TMS-TGCGCA)(2), where TMS denotes trimethoxystilbene carboxamides that are 5'-tethered to the DNA. The stilbenes, for which intercalation is conformationally accessible, stack on the terminal T:A base pairs of an undisturbed B-form duplex. Two conformations, differing by the orientation of the stilbene relative to the terminal base pair, are observed, indicating that the flip rate is slow for the pi-stacked aromatic ring system. The trimethoxystilbene is known to greatly increase base pairing fidelity at the terminus. Here we show that it gauges the size of the T:A base pair by embracing the 2'-methylene group of the terminal dA residue of the unmodified terminus with its methoxy "arms", but that it does not engage the entire base pair in pi-stacking. Mismatched base pairs with their altered geometry will not allow for the same embracing interaction. On the basis of the current structure, a trimethoxychrysene carboxamide is proposed as a ligand with increased pi-stacking surface and possible applications as improved fidelity-enhancing element.

5'-Tethered stilbene derivatives as fidelity- and affinity-enhancing modulators of DNA duplex stability.

A series of 5'-linked stilbene-DNA conjugates with different substituents in the distal aromatic ring of the stilbene was prepared, and the effect of the modifications on duplex stability was determined via UV-melting curves. A trimethoxystilbene derivative as a 5'-substituent increases duplex melting points by up to 12.2 degrees C per modification. With this alkoxystilbene substituent, terminal mismatches in DNA duplexes lower the melting point by up to 23.4 degrees C over the perfectly matched control, whereas terminal mismatches in unmodified DNA cause melting point depressions of no more than 6.1 degrees C. An aminomethylstilbene substituent linked to an oligopyrrolamide minor groove binder increases the melting point of an all-A/T decamer by up to 32.7 degrees C, thus shifting the melting point into a range typical for duplexes with statistical G/C-content. An affinity- and selectivity-enhancing effect was also observed when the trimethoxystilbene cap was employed on a small DNA microarray. The phosphoramidite of the trimethoxystilbene can be readily employed in automatic DNA synthesis, facilitating the generation of DNA chips with improved fidelity.