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1. A combinatorial system to examine the enzymatic repair of multiply damaged DNA substrates

   https://doi.org/10.1093/nar/gkac530  

   Hsu, Chia Wei ; Conrad, James W ; Sowers, Mark L ; Baljinnyam, Tuvshintugs ; Herring, Jason L ; Hackfeld, Linda C ; Hatch, Sandra S ; Sowers, Lawrence C ( July 2022 , Nucleic Acids Research)

   Abstract DNA damage drives genetic mutations that underlie the development of cancer in humans. Multiple pathways have been described in mammalian cells which can repair this damage. However, most work to date has focused upon single lesions in DNA. We present here a combinatorial system which allows assembly of duplexes containing single or multiple types of damage by ligating together six oligonucleotides containing damaged or modified bases. The combinatorial system has dual fluorescent labels allowing examination of both strands simultaneously, in order to study interactions or competition between different DNA repair pathways. Using this system, we demonstrate how repair of oxidative damage in one DNA strand can convert a mispaired T:G deamination intermediate into a T:A mutation. We also demonstrate that slow repair of a T:G mispair, relative to a U:G mispair, by the human methyl-binding domain 4 DNA glycosylase provides a competitive advantage to competing repair pathways, and could explain why CpG dinucleotides are hotspots for C to T mutations in human tumors. Data is also presented that suggests repair of closely spaced lesions in opposing strands can be repaired by a combination of short and long-patch base excision repair and simultaneous repair of multiply damage sites can potentially lead to lethal double strand breaks. 

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2. Measurement of deaminated cytosine adducts in DNA using a novel hybrid thymine DNA glycosylase

   https://doi.org/10.1016/j.jbc.2022.101638  

   Hsu, Chia Wei ; Sowers, Mark L. ; Baljinnyam, Tuvshintugs ; Herring, Jason L. ; Hackfeld, Linda C. ; Tang, Hui ; Zhang, Kangling ; Sowers, Lawrence C. ( March 2022 , Journal of Biological Chemistry)

   The hydrolytic deamination of cytosine and 5-methylcytosine drives many of the transition mutations observed in human cancer. The deamination-induced mutagenic intermediates include either uracil or thymine adducts mispaired with guanine. While a substantial array of methods exist to measure other types of DNA adducts, the cytosine deamination adducts pose unusual analytical problems, and adequate methods to measure them have not yet been developed. We describe here a novel hybrid thymine DNA glycosylase (TDG) that is comprised of a 29-amino acid sequence from human TDG linked to the catalytic domain of a thymine glycosylase found in an archaeal thermophilic bacterium. Using defined-sequence oligonucleotides, we show that hybrid TDG has robust mispair-selective activity against deaminated U:G and T:G mispairs. We have further developed a method for separating glycosylase-released free bases from oli- gonucleotides and DNA followed by GC–MS/MS quantification. Using this approach, we have measured for the first time the levels of total uracil, U:G, and T:G pairs in calf thymus DNA. The method presented here will allow the measurement of the for- mation, persistence, and repair of a biologically important class of deaminated cytosine adducts. 

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3. Systematic Assessment of the Flexibility of Uracil Damaged DNA

   Orndorff, Paul B. ; van der Vaart, Arjan ( January 2023 , Journal of biomolecular structure and dynamics)

   Uracil is a common DNA lesion which is recognized and removed by uracil DNA-glycosylase (UDG) as a part of the base excision repair pathway. Excision proceeds by base flipping, and UDG efficiency is thought to depend on the ease of deformability of the bases neighboring the lesion. We used molecular dynamics simulations to assess the flexibility of a large library of dsDNA strands, containing all tetranucleotide motifs with U:A, U:G, T:A or C:G base pairs. Our study demonstrates that uracil damaged DNA largely follows trends in flexibility of undamaged DNA. Measured bending persistence lengths, groove widths, step parameters and base flipping propensities demonstrate that uracil increases the flexibility of DNA, and that U:G base paired strands are more flexible than U:A strands. Certain sequence contexts are more deformable than others, with a key role for the 3’ base next to uracil. Flexibilities are large when this base is an A or G, and repressed for a C or T. A 5’ T adjacent to the uracil strongly promotes flexibility, but other 5’ bases are less influential. DNA bending is correlated to step deformations and base flipping, and bending aids flipping. Our study implies that the link between substrate flexibility and UDG efficiency is widely valid, helps explain why UDG prefers to bind U:G base paired strands, and suggests that the DNA bending angle of the UDG-substrate complex is optimal for base flipping. 

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4. Shelterin reduces the accessibility of telomeric overhangs

   https://doi.org/10.1093/nar/gkac1176  

   Shiekh, Sajad ; Jack, Amanda ; Saurabh, Ayush ; Mustafa, Golam ; Kodikara, Sineth G. ; Gyawali, Prabesh ; Hoque, Mohammed Enamul ; Pressé, Steve ; Yildiz, Ahmet ; Balci, Hamza ( December 2022 , Nucleic Acids Research)

   Telomeres terminate with a 50–300 bases long single-stranded G-rich overhang, which can be misrecognized as a DNA damage repair site. Shelterin plays critical roles in maintaining and protecting telomere ends by regulating access of various physiological agents to telomeric DNA, but the underlying mechanism is not well understood. Here, we measure how shelterin affects the accessibility of long telomeric overhangs by monitoring transient binding events of a short complementary peptide nucleic acid (PNA) probe using FRET-PAINT in vitro. We observed that the POT1 subunit of shelterin reduces the accessibility of the PNA probe by ∼2.5-fold, indicating that POT1 effectively binds to and protects otherwise exposed telomeric sequences. In comparison, a four-component shelterin stabilizes POT1 binding to the overhang by tethering POT1 to the double-stranded telomeric DNA and reduces the accessibility of telomeric overhangs by ∼5-fold. This enhanced protection suggests shelterin restructures the junction between single and double-stranded telomere, which is otherwise the most accessible part of the telomeric overhang.

    

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5. In vivo fluorescent TUNEL detection of single stranded DNA gaps and breaks induced by dnaB helicase mutants in Escherichia coli

   Behrmann, Megan S ; Trakselis, Michael A. ( August 2022 , Methods in enzymology)

   Trakselis, Michael A. (Ed.)

   The genome of prokaryotes can be damaged by a variety of endogenous and exogenous factors, including reactive oxygen species, UV exposure, and antibiotics. To better understand these repair processes and the impact they may have on DNA replication, normal genome maintenance processes can be perturbed by removing or editing associated genes and monitoring DNA repair outcomes. In particular, the replisome activities of DNA unwinding by the helicase and DNA synthesis by the polymerase must be tightly coupled to prevent any appreciable single strand DNA (ssDNA) from accumulating and amplifying genomic stress. If decoupled, vulnerable ssDNA would persist, likely leading to double strand breaks (DSBs) or requiring replication restart mechanisms downstream of a stall. In either case, free 3'-OH strands would exist, resulting from ssDNA gaps in the leading strand or complete DSBs. Terminal deoxyribonucleotide transferase (TdT)-mediated dUTP nick end labeling (TUNEL) can enzymatically label ssDNA ends with bromo-deoxy uridine triphosphate (BrdU) to detect free 3'-OH DNA ends in the E. coli genome. Labeled DNA ends can be detected and quantified using fluorescence microscopy or flow cytometry. This methodology is useful in applications where in situ investigation of DNA damage and repair are of interest, including effects from enzyme mutations or deletions and exposure to various environmental conditions. 

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