Development of synthetic agents that recognize double-stranded DNA (dsDNA) is a long-standing goal that is inspired by the promise for tools that detect, regulate and modify genes. Progress has been made with triplex-forming oligonucleotides, PNAs, and polyamides, but substantial efforts are currently devoted to the development of alternative strategies that overcome limitations observed with the classic approaches. In 2005, we introduced Invader Locked Nucleic Acids (LNAs), i.e., double-stranded probes that are activated for mixed-sequence recognition of dsDNA through modification with ‘+1 interstrand zippers’ of 2’-N-(pyren-1-yl)methyl-2’-amino-α-L-LNA monomers. Despite promising preliminary results, progress has been slow due to the synthetic complexity of the building blocks. Here, we describe a study that led to the identification of two simpler classes of Invader monomers. We compare thermal denaturation characteristics of double-stranded probes featuring different interstrand zippers of pyrene-functionalized monomers based on 2’-amino-α-L-LNA, 2’-N-methyl-2’-amino-DNA, and RNA scaffolds. Insights from fluorescence spectroscopy, molecular modeling and NMR spectroscopy are used to elucidate the structural factors that govern probe activation. We demonstrate that probes with +1 zippers of 2’-O-(pyren-1-yl)methyl-RNA or 2’-N-methyl-2’-N-(pyren-1-yl)methyl-2’-amino-DNA monomers recognize DNA hairpins with similar efficiency as original Invader LNAs. Access to synthetically simple monomers will accelerate the use of Invader-mediated dsDNA-recognition for applications in molecular biology and nucleic acid diagnostics.
N2′-Pyrene-functionalized 2′-amino-α-L-LNAs (Locked Nucleic Acids) display extraordinary affinity toward complementary DNA targets due to favorable preorganization of the pyrene moieties for hybridization-induced intercalation. Unfortunately, the synthesis of these monomers is challenging (~20 steps, <3% overall yield), which has precluded full characterization of DNA-targeting applications based on these materials. Access to more readily accessible functional mimics would be highly desirable. Here we describe short synthetic routes toward a series of O2′-intercalator-functionalized uridine and N2′-intercalator-functionalized 2′-N-methyl-2′-aminouridine monomers and demonstrate – via thermal denaturation, UV-visible absorption and fluorescence spectroscopy experiments – that several of them mimic the DNA-hybridization properties of N2′-pyrene-functionalized 2′-amino-α-L-LNAs. For example, oligodeoxyribonucleotides (ONs) modified with 2′-O-(coronen-1-yl)methyluridine monomer Z, 2′-O-(pyren-1-yl)methyluridine monomer Y or 2′-N-(pyren-1-ylmethyl)-2′-N-methylaminouridine monomer Q, display prominent increases in thermal affinity toward complementary DNA relative to reference strands (average ΔTm/mod up to +12 °C), pronounced DNA-selectivity, and higher target specificity than 2′-amino-β-L-LNA benchmark probes. In contrast, ONs modified with 2′-O-(2-napthyl)uridine monomer W, 2′-O-(pyren-1-yl)uridine monomer X or 2′-N-(pyren-1-ylcarbonyl)-2′-N-methylaminouridine monomer S display very low affinity toward DNA targets. This demonstrates that even conservative alterations in linker chemistry, linker length and surface area of the appended intercalators have marked impact on DNA-hybridization characteristics. Straightforward access to high-affinity building blocks such as Q/Y/Z is likely to accelerate their use in DNA-targeting applications within nucleic acid based diagnostics, therapeutics, and material science.
The discovery of two new classes of catalysts for hydrazone and oxime formation in water at neutral pH, namely 2-aminophenols and 2-(aminomethyl)benzimidazoles, is reported. Kinetics studies in aqueous solutions at pH 7.4 revealed rate enhancements up to 7-fold greater than with classic aniline catalysis. 2-(Aminomethyl)benzimidazoles were found to be effective catalysts with otherwise challenging aryl ketone substrates.
The invasion has begun: Invaders are shown to recognize DNA hairpins in cell‐free assays and chromosomal DNA during non‐denaturing fluorescence in situ hybridization (nd‐FISH) experiments. As Invaders are devoid of inherent sequence limitations, many previously inaccessible DNA targets could become accessible to exogenous control with important ramifications for karyotyping, in vivo imaging, and gene regulation.
Formaldehyde is universally employed to fix tissue specimens, where it forms hemiaminal and aminal adducts with biomolecules, hindering the ability to retrieve molecular information. Common methods for removing these adducts involve extended heating, which can cause extensive degradation of nucleic acids, particularly RNA. Here we show that water-soluble bifunctional catalysts (anthranilates and phosphanilates) speed the reversal of formaldehyde adducts of mononucleotides over standard buffers. Studies with formaldehyde-treated RNA oligonucleotides show that the catalysts enhance adduct removal, restoring unmodified RNA at 37 °C even when extensively modified, and avoiding high temperatures that promote RNA degradation. Experiments with formalin-fixed, paraffin-embedded cell samples show that the catalysis is compatible with common RNA extraction protocols, with detectable RNA yields increased by 1.5–2.4 fold using a catalyst under optimized conditions, and by 7–25 fold compared to a commercial kit. Such catalytic strategies show promise for general use in reversing formaldehyde adducts in clinical specimens.
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