Interstrand DNA Cross-Links Derived from Reaction of a 2-Aminopurine Residue with an Abasic Site.

Efficient methods for the site-specific installation of structurally defined interstrand cross-links in duplex DNA may be useful in a wide variety of fields. The work described here developed a high-yield synthesis of chemically stable interstrand cross-links resulting from a reductive amination reaction between an abasic site and the noncanonical nucleobase 2-aminopurine in duplex DNA. Results from footprinting, liquid chromatography-mass spectrometry, and stability studies support the formation of an N2-alkylamine attachment between the 2-aminopurine residue and the Ap site. The reaction performs best when the 2-aminopurine residue on the opposing strand is offset 1 nt to the 5'-side of the abasic site. The cross-link confers substantial resistance to thermal denaturation (melting). The cross-linking reaction is fast (complete in 4 h), employs only commercially available reagents, and can be used to generate cross-linked duplexes in sufficient quantities for biophysical, structural, and DNA repair studies.

Preparation and Purification of Oligodeoxynucleotide Duplexes Containing a Site-Specific, Reduced, Chemically Stable Covalent Interstrand Cross-Link Between a Guanine Residue and an Abasic Site.

Methods for the preparation of DNA duplexes containing interstrand covalent cross-links may facilitate research in the fields of biochemistry, molecular biology, nanotechnology, and materials science. Here we report methods for the synthesis and isolation of DNA duplexes containing a site-specific, chemically stable, reduced covalent interstrand cross-link between a guanine residue and an abasic site. The method uses experimental techniques and equipment that are common in most biochemical laboratories and inexpensive, commercially available oligonucleotides and reagents.

Selective covalent capture of a DNA sequence corresponding to a cancer-driving C>G mutation in the KRAS gene by a chemically reactive probe: optimizing a cross-linking reaction with non-canonical duplex structures.

Covalent reactions are used in the detection of various biological analytes ranging from low molecular weight metabolites to protein-protein complexes. The detection of specific nucleic acid sequences is important in molecular biology and medicine but covalent approaches are less common in this field, in part, due to a deficit of simple and reliable reactions for the covalent capture of target sequences. Covalent anchoring can prevent the denaturation (melting) of probe-target complexes and causes signal degradation in typical hybridization-based assays. Here, we used chemically reactive nucleic acid probes that hybridize with, and covalently capture, a target sequence corresponding to a cancer-driving variant of the human KRAS gene. Our approach exploits a reductive amination reaction to generate a stable covalent attachment between an abasic site in the probe strand and a guanine mutation at position 35 in the KRAS gene sequence. Importantly, systematic variation of the probe sequence in a manner that formally introduces non-canonical structures such as bulges and mispairs into the probe-target duplex led to probes with dramatically improved cross-linking properties. An optimized abasic site-containing probe enabled simultaneous quantitative detection of both mutant and wild-type KRAS sequences in mixtures.

Generation and Single-Molecule Characterization of a Sequence-Selective Covalent Cross-Link Mediated by Mechlorethamine at a C-C Mismatch in Duplex DNA for Discrimination of a Disease-Relevant Single Nucleotide Polymorphism.

Many strategies for the detection of nucleic acid sequence rely upon Watson-Crick hybridization of a probe strand to the target strand, but the reversible nature of nucleic acid hybridization presents an inherent challenge: short probes that provide high target specificity have relatively low target affinity resulting in signal losses. Sequence-specific covalent cross-linking reactions have the potential to provide both selective target capture and durable signal. We explore a novel approach involving sequence-specific covalent cross-linking of a probe to target DNA combined with single-molecule nanopore detection of the cross-linked DNA. Here, we exploited the selective reaction of mechlorethamine at a C-C mismatch for covalent capture of a target DNA sequence corresponding to a cancer-driving mutation at position 1799 of the human BRAF kinase gene. We then demonstrated that the α-hemolysin protein nanopore can be employed for the unambiguous, single-molecule detection of the cross-linked probe-target complex. Cross-linked DNA generates an unmistakable deep and persistent current block (≥5 s) that is easily distinguished from the microsecond and millisecond blocks generated by translocation of single-stranded DNA and uncross-linked duplexes through the nanopore.

Sequence-Specific Covalent Capture Coupled with High-Contrast Nanopore Detection of a Disease-Derived Nucleic Acid Sequence.

Hybridization-based methods for the detection of nucleic acid sequences are important in research and medicine. Short probes provide sequence specificity, but do not always provide a durable signal. Sequence-specific covalent crosslink formation can anchor probes to target DNA and might also provide an additional layer of target selectivity. Here, we developed a new crosslinking reaction for the covalent capture of specific nucleic acid sequences. This process involved reaction of an abasic (Ap) site in a probe strand with an adenine residue in the target strand and was used for the detection of a disease-relevant T→A mutation at position 1799 of the human BRAF kinase gene sequence. Ap-containing probes were easily prepared and displayed excellent specificity for the mutant sequence under isothermal assay conditions. It was further shown that nanopore technology provides a high contrast-in essence, digital-signal that enables sensitive, single-molecule sensing of the cross-linked duplexes.

A role for the base excision repair enzyme NEIL3 in replication-dependent repair of interstrand DNA cross-links derived from psoralen and abasic sites.

Interstrand DNA-DNA cross-links are highly toxic lesions that are important in medicinal chemistry, toxicology, and endogenous biology. In current models of replication-dependent repair, stalling of a replication fork activates the Fanconi anemia pathway and cross-links are "unhooked" by the action of structure-specific endonucleases such as XPF-ERCC1 that make incisions flanking the cross-link. This process generates a double-strand break, which must be subsequently repaired by homologous recombination. Recent work provided evidence for a new, incision-independent unhooking mechanism involving intrusion of a base excision repair (BER) enzyme, NEIL3, into the world of cross-link repair. The evidence suggests that the glycosylase action of NEIL3 unhooks interstrand cross-links derived from an abasic site or the psoralen derivative trioxsalen. If the incision-independent NEIL3 pathway is blocked, repair reverts to the incision-dependent route. In light of the new model invoking participation of NEIL3 in cross-link repair, we consider the possibility that various BER glycosylases or other DNA-processing enzymes might participate in the unhooking of chemically diverse interstrand DNA cross-links.

A New Cross-Link for an Old Cross-Linking Drug: The Nitrogen Mustard Anticancer Agent Mechlorethamine Generates Cross-Links Derived from Abasic Sites in Addition to the Expected Drug-Bridged Cross-Links.

Nitrogen mustard anticancer drugs generate highly reactive aziridinium ions that alkylate DNA. Monoadducts arising from reaction with position N7 of guanine residues are the major DNA adducts generated by these agents. Interstrand cross-links in which the drug bridges position N7 of two guanine residues are formed in low yields relative to those of the monoadducts but are generally thought to be central to medicinal activity. The N7-alkylguanine residues generated by nitrogen mustards are depurinated to yield abasic (Ap) sites in duplex DNA. Here, we show that Ap sites generated by the nitrogen mustard mechlorethamine lead to interstrand cross-links of a type not previously associated with this drug. Gel electrophoretic data were consistent with early evolution of the expected drug-bridged cross-links, followed by the appearance of Ap-derived cross-links. The evidence is further consistent with a reaction pathway involving alkylation of a guanine residue in a 5'-GT sequence, followed by depurination to generate the Ap site, and cross-link formation via reaction of the Ap aldehyde residue with the opposing adenine residue at this site [Price, N. E., Johnson, K. M., Wang, J., Fekry, M. I., Wang, Y., and Gates, K. S. (2014) J. Am. Chem. Soc. 136, 3483-3490]. The monofunctional DNA-alkylating agents 2-chloro-N,N-diethylethanamine 5, (2-chloroethyl)ethylsulfide 6, and natural product leinamycin similarly were found to induce the formation of Ap-derived cross-links in duplex DNA. This work provides the first characterization of Ap-derived cross-links at sequences in which a cytosine residue is located directly opposing the Ap site. Cross-linking processes of this type could be relevant in medicine and biology because Ap sites with directly opposing cytosine residues occur frequently in genomic DNA via spontaneous or enzymatic depurination of guanine and N7-alkylguanine residues.