DNA trinucleotide repeats, particularly CXG, are common within the human genome. However, expansion of trinucleotide repeats is associated with a number of disorders, including Huntington disease, spinobulbar muscular atrophy and spinocerebellar ataxia. In these cases, the repeat length is known to correlate with decreased age of onset and disease severity. Repeat expansion of (CAG)n, (CTG)n and (CGG)n trinucleotides may be related to the increased stability of alternative DNA hairpin structures consisting of CXG-CXG triads with X-X mismatches. Small-molecule ligands that selectively bound to CAG repeats could provide an important probe for determining repeat length and an important tool for investigating the in vivo repeat extension mechanism. Here we report that napthyridine-azaquinolone (NA, 1) is a ligand for CAG repeats and can be used as a diagnostic tool for determining repeat length. We show by NMR spectroscopy that binding of NA to CAG repeats induces the extrusion of a cytidine nucleotide from the DNA helix.
We have synthesized the first surface plasmon resonance (SPR) sensor that detects cytosine-cytosine (C[bond]C) mismatches in duplex DNA by immobilizing aminonaphthyridine dimer on the gold surface. The ligand consisting of two 2-aminonaphthyridine chromophores and an alkyl linker connecting them strongly stabilized the C[bond]C mismatches regardless of the flanking sequences. The fully matched duplexes were not stabilized at all under the same conditions. The C[bond]T, C[bond]A, and T[bond]T mismatches were also stabilized with a reduced efficiency. SPR analyses of mismatch-containing 27-mer duplexes were performed with the sensor surface on which the aminonaphthyridine dimer was immobilized. The response for the C[bond]C mismatch in 5'-GCC-3'/3'-CCG-5' was about 83 times stronger than that obtained for the fully matched duplex. The sensor successfully detects the C[bond]C mismatch at the concentration of 10 nM. SPR responses are proportional to the concentration of the C[bond]C mismatch in a range up to 200 nM. Aminonaphthyridine dimer could bind strongly to the C[bond]C mismatches having 10 possible flanking sequences with association constants in the order of 10(6) M(-1). The facile protonation of 2-aminonaphthyridine chromophore at pH 7 producing the hydrogen-bonding surface complementary to that of cytosine was most likely due to the remarkably high selectivity of 1 to the C[bond]C mismatch.
We have discovered a new molecule naphthyridine-azaquinolone hybrid (Npt-Azq) that strongly stabilized the guanine-adenine (G-A) mismatch in duplex DNA. In the presence of Npt-Azq, the melting temperature (T(m)) of 5'-d(CTA ACG GAA TG)-3'/3'-d(GAT TGA CTT AC)-5' containing a single G-A mismatch increased by 15.4 degrees C, whereas fully matched duplex increased its T(m) only by 2.2 degrees C. Npt-Azq was immobilized on the sensor surface for the surface plasmon resonance (SPR) assay to examine SPR detection of duplexes containing a G-A mismatch. Distinct SPR signals were observed when 27mer DNA containing a G-A mismatch was analyzed by the Npt-Azq immobilized sensor surfaces, whereas the signal of the fully matched duplex was approximately 6-fold weaker in intensity. The SPR signals for the G-A mismatch were proportional to the concentration of DNA in a range up to 1 microM, confirming that the SPR signal is in fact due to the binding of the G-A mismatch to Npt-Azq immobilized on the surface. Examination of all 16 G-A mismatches regarding the flanking sequence revealed that the sensor surface reported here is applicable to eight flanking sequences, covering 50% of all possible G-A mismatches.
Repair glycosylases locate and excise damaged bases from DNA, playing central roles in preservation of the genome and prevention of disease. Two key glycosylases, Fpg and hOGG1, function to remove the mutagenic oxidized base 8-oxoG (OG) from DNA. To investigate the relative contributions of conformational preferences, leaving group ability, enzyme-base hydrogen bonding and nucleobase shape on damage recognition by these glycosylases, a series of four substituted indole nucleosides, based on the parent OG nonpolar isostere 2Cl-4F-indole, were tested as possible direct substrates of these enzymes in the context of 30 base pair duplexes paired with C. Surprisingly, single-turnover experiments revealed that Fpg-catalyzed base removal activity of two of the nonpolar analogs was superior to the native OG substrate. The hOGG1 glycosylase was also found to catalyze removal of three of the nonpolar analogs, albeit considerably less efficiently than removal of OG. Of note, the analog that was completely resistant to hOGG1-catalyzed excision has a chloro-substituent at the position of NH7 of OG implicating the importance of recognition of this position in catalysis. Both hOGG1 and Fpg retained high affinity for the duplexes containing the nonpolar isosteres. These studies show that hydrogen bonds between base and enzyme are not needed for efficient damage recognition and repair by Fpg and underscore the importance of facile extrusion from the helix in its damaged base selection. In contrast, damage removal by hOGG1 is sensitive both to hydrogen bonding groups and nucleobase shape. The relative rates of excision of the analogs with the two glycosylases highlight key differences in their mechanisms of damaged base recognition and removal.
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