We report the use of thermodynamic measurements in a self-complementary DNA duplex (5′-dXCGCGCG) 2 , where X is an unpaired natural or nonnatural deoxynucleoside, to study the forces that stabilize aqueous aromatic stacking in the context of DNA. Thermal denaturation experiments show that the core duplex (lacking X) is formed with a free energy (37 °C) of −8.1 kcal·mol −1 in a pH 7.0 buffer containing 1 M Na + . We studied the effects of adding single dangling nucleosides (X) where the aromatic "base" is adenine, guanine, thymine, cytosine, pyrrole, benzene, 4-methylindole, 5-nitroindole, trimethylbenzene, difluorotoluene, naphthalene, phenanthrene, and pyrene. Adding these dangling residues is found to stabilize the duplex by an additional −0.8 to −3.4 kcal·mol −1 . At 5 μM DNA concentration, T m values range from 41.7 °C (core sequence) to 64.1 °C (with dangling pyrene residues). For the four natural bases, the order of stacking ability is A > G ≥ T = C. The nonpolar analogues stack more strongly in general than the more polar natural bases. The stacking geometry was confirmed in two cases (X = adenine and pyrene) by 2-D NOESY experiments. Also studied is the effect of ethanol cosolvent on the stacking of natural bases and pyrene. Stacking abilities were compared to calculated values for hydrophobicity, dipole moment, polarizability, and surface area. In general, hydrophobic effects are found to be larger than other effects stabilizing stacking (electrostatic effects, dispersion forces); however, the natural DNA bases are found to be less dependent on hydrophobic effects than are the more nonpolar compounds. The results also point out strategies for the design nucleoside analogues that stack considerably more strongly than the natural bases; such compounds may be useful in stabilizing designed DNA structures and complexes.
Noncovalent interactions between aromatic molecules are widely believed to be important contributing factors in the stabilization of organized structure in biological macromolecules. 1,2 Among the most significant aromatic-aromatic interactions are those found in helical nucleic acid structures. Since the identity of the nearest neighbors to a given base pair is the best single predictor of thermodynamics in DNA duplexes, 3 it is clear that aromatic π-π interactions are crucial to the stabilization of these structures. 4 While there have been a considerable number of theoretical studies aimed at modeling the π-π interaction in DNA, 5 there have been remarkably few experimental studies specifically addressing the thermodynamics of stacking (separate from base pairing) in DNA itself. 6 For that reason we have undertaken a study of aromatic stacking in the context of duplex DNA, and we hope to begin to elucidate what are the important forces which stabilize this organized structure. We report here the first experimental comparison of the stacking abilities of natural DNA bases and of nonnatural aromatic analogs in double-stranded DNA.To separate stacking from pairing (hydrogen-bonding) interactions in duplex DNA we placed the natural or nonnatural nucleotide of interest in a "dangling" position (without a pairing partner) at the end of a base-paired duplex (Figure 1). 7 The resulting stabilization of the duplex by the dangling base can be measured by thermal denaturation experiments, with comparison to the duplex lacking the added nucleotide.Electrostatic effects resulting from such localized charge have been implicated both in the stabilization and in the geometry of aromatic stacking. 5 To examine such effects we compared not only natural DNA bases but also nonpolar molecules with similar shape and surface area. Thus, we compared the DNA base thymine (1) and adenine (3) with their respective nonpolar isosteres difluorotoluene (2) and 4-methylindole (4). 9 We also compared the stacking of the aromatic hydrocarbons benzene (5), naphthalene (6), phenanthrene (7), and pyrene (8). The synthesis of these nucleoside analogs has been reported. [10][11][12][13] Results of the thermodynamic measurements made at pH 7.0 and 1 M NaCl are presented in Table 1 Supporting Information Available:Plots of thermodynamic data, sample thermal melting profiles, and proton NMR spectra (3 pages). See any current masthead page for ordering and Internet access instructions. Measurement of the duplexes with dangling thymine and adenine residues shows, perhaps not surprisingly, that the purine stacks on the duplex more strongly than the smaller pyrimidine base. The two unpaired deoxyadenosines add 2.0 kcal of stabilizing interaction to the selfcomplementary sequence, and thymines add 1.1 kcal to the duplex stability. This relative stacking ability is as predicted from nearest-neighbor parameters 3 and is consistent with dangling-end studies carried out in RNA. 7 Interestingly, the data show that the nonpolar DNA base mimics stack cons...
We report the properties of hydrophobic isosteres of pyrimidines and purines in synthetic DNA duplexes. Phenyl nucleosides 1 and 2 are nonpolar isosteres of the natural thymidine nucleoside, and indole nucleoside 3 is an analog of the complementary purine 2-aminodeoxyadenosine. The nucleosides were incorporated into synthetic oligodeoxynucleotides and were paired against each other and against the natural bases. Thermal denaturation experiments were used to measure the stabilities of the duplexes at neutral pH. It is found that the hydrophobic base analogs are nonselective in pairing with the four natural bases but selective for pairing with each other rather than with the natural bases. For example, compound 2 selectively pairs with itself rather than with A, T, G, or C; the magnitude of this selectivity is found to be 6.5-9.3 °C in Tm or 1.5-1.8 kcal/mol in free energy (25 °C). All possible hydrophobic pairing combinations of 1, 2, and 3 were examined. Results show that the pairing affinity depends on the nature of the pairs and on position in the duplex. The highest affinity pairs are found to be the 1-1 and 2-2 self-pairs and the 1-2 heteropair. The best stabilization occurs when the pairs are placed at the ends of duplexes rather than internally; the internal pairs may be destabilized by imperfect steric mimicry which leads to non-ideal duplex structure. In some cases the hydrophobic pairs are significantly stabilizing to the DNA duplex; for example, when situated at the end of a duplex, the 1-1 pair is more stabilizing than a T-A pair. When situated internally, the affinity of the 1-1 pair is the same as, or slightly better than, the analogous T-T mismatch pair, which is known to have two hydrogen bonds. The studies raise the possibility that hydrogen bonds may not always be required for the formation of stable duplex DNA-like structure. In addition, the results point out the importance of solvation and desolvation in natural base pairing, and lend new support to the idea that hydrogen bonds in DNA may be more important for specificity of pairing than for affinity. Finally, the study raises the possibility of using these or related base pairs to expand the genetic code beyond the natural A-T and G-C pairs.
Described are the design, synthesis, and structures of three nonpolar nucleoside isosteres to be used as probes of noncovalent bonding in DNA and as isosteric replacements for the natural nucleosides in designed nucleic acid structures. Reaction of substituted aryl Grignards with 3′,5′-bis-O-toluoyl-α-deoxyibofuranosyl chloride and subsequent deprotection with sodium methoxide in methanol afforded the two β-C-nucleoside pyrimidine analogs 1 and 2. The dimethylindolyl nucleoside 3, a purine isostere, was obtained by a nucleophilic displacement on α-chlorodeoxyribofuranose by the sodium salt of 4,6-dimethylindole, followed by deprotection. Regio-and stereochemistry of the products were established with NOE difference spectra and 1 H NMR splitting patterns. Analogs 1 and 2 are nonpolar isosteres of thymidine, and nucleoside 3 is an isostere of 2-aminodeoxyadenosine, the triply-bonded Watson-Crick partner of thymidine. Semiempirical AM1 calculations were carried out to provide bond length information to assess structural similarities between the isosteres and their natural counterparts.
Agents have been designed and synthesized which target the dimerization interface of HIV-1 protease. These agents, which contain cross-linked peptides from the N- and C-termini of the protease, both inhibit HIV-1 protease activity and decrease the amount of protease dimer in solution as measured by size exclusion chromatography, protein crosslinking, and protease fluorescence studies. Additionally we have shown that active site-targeted agents inhibit HIV-1 protease activity but have little effect on protease dimerization. These data support the claim that inhibition with the crosslinked agents is based on a decrease in the amount of protease homodimer in solution which in turn is responsible for a decrease in the activity of the protease.
[reaction: see text] A general demonstration of orthogonal selectivity of the Liebeskind-Srogl cross-coupling protocol compared to the Suzuki-Miyaura and Stille variants is reported.
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