Hydrolytic loss of nucleobases from the deoxyribose backbone of DNA is one of the most common unavoidable types of damage in synthetic and cellular DNA. The reaction generates abasic sites in DNA, and it is important to understand the properties of these lesions. The acidic nature of the α-protons of the ring-opened abasic aldehyde residue facilitates the β-elimination of the 3′-phosphoryl group. This reaction is expected to generate a DNA strand break with a phosphoryl group on the 5′-terminus and a trans-α,β-unsaturated aldehyde residue on the 3′-terminus; however, a handful of studies have identified noncanonical sugar remnants on the 3′-terminus, suggesting that the products arising from strand cleavage at apurinic/apyrimidinic sites in DNA may be more complex than commonly thought. We characterized the strand cleavage induced by the treatment of an abasic site-containing DNA oligonucleotide with heat, NaOH, piperidine, spermine, and the base excision repair glycosylases Fpg and Endo III. The results showed that under multiple conditions, cleavage at an abasic site in a DNA oligomer generated noncanonical sugar remnants including cis-α,β-unsaturated aldehyde, 2deoxyribose, and 3-thio-2,3-dideoxyribose products on the 3′-terminus of the strand break.
Interstrand
DNA cross-links (ICLs) are cytotoxic because they block
the strand separation required for read-out and replication of the
genetic information in duplex DNA. The unavoidable formation of ICLs
in cellular DNA may contribute to aging, neurodegeneration, and cancer.
Here, we describe the formation and properties of a structurally complex
ICL derived from an apurinic/apyrimidinic (AP) site, which is one
of the most common endogenous lesions in cellular DNA. The results
characterize a cross-link arising from aza-Michael addition of the N
2-amino group of a guanine residue to the electrophilic
sugar remnant generated by spermine-mediated strand cleavage at an
AP site in duplex DNA. An α,β-unsaturated iminium ion
is the critical intermediate involved in ICL formation. Studies employing
the bacteriophage φ29 polymerase provided evidence that this
ICL can block critical DNA transactions that require strand separation.
The results of biochemical studies suggest that this complex strand
break/ICL might be repaired by a simple mechanism in which the 3′-exonuclease
action of the enzyme apurinic/apyrimidinic endonuclease (APE1) unhooks
the cross-link to initiate repair via the single-strand break repair
pathway.
Abstract:The described mechanochemical methodology is an example of a proof-of-concept in which solution-based tedious, poor yielding, and difficult syntheses of pyrazaacenes are achieved under solvent-free ball-milling conditions; the method is easy, high yielding, time-efficient, and environmentally benign. The synthesized compounds also include pyrazaacenes (N-heteroacenes) that are octacene analogues containing pyrene building blocks. The compounds were sparingly soluble in
The NEIL3 DNA glycosylase maintains genome integrity during replication by excising oxidized bases from single-stranded DNA (ssDNA) and unhooking interstrand cross-links (ICLs) at fork structures. In addition to its N-terminal catalytic glycosylase domain, NEIL3 contains two tandem C-terminal GRF-type zinc fingers that are absent in the other NEIL paralogs. ssDNA binding by the GRF-ZF motifs helps recruit NEIL3 to replication forks converged at an ICL, but the nature of DNA binding and the effect of the GRF-ZF domain on catalysis of base excision and ICL unhooking is unknown. Here, we show that the tandem GRF-ZFs of NEIL3 provide affinity and specificity for DNA that is greater than each individual motif alone. The crystal structure of the GRF domain shows the tandem ZF motifs adopt a flexible head-to-tail configuration well-suited for binding to multiple ssDNA conformations. Functionally, we establish that the NEIL3 GRF domain inhibits glycosylase activity against monoadducts and ICLs. This autoinhibitory activity contrasts GRF-ZF domains of other DNA processing enzymes, which typically use ssDNA binding to enhance catalytic activity, and suggests that the C-terminal region of NEIL3 is involved in both DNA damage recruitment and enzymatic regulation.
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