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1. High-resolution mapping demonstrates inhibition of DNA excision repair by transcription factors

   https://doi.org/10.7554/eLife.73943  

   Duan, Mingrui ; Sivapragasam, Smitha ; Antony, Jacob S ; Ulibarri, Jenna ; Hinz, John M ; Poon, Gregory MK ; Wyrick, John J ; Mao, Peng ( March 2022 , eLife)

   DNA base damage arises frequently in living cells and needs to be removed by base excision repair (BER) to prevent mutagenesis and genome instability. Both the formation and repair of base damage occur in chromatin and are conceivably affected by DNA-binding proteins such as transcription factors (TFs). However, to what extent TF binding affects base damage distribution and BER in cells is unclear. Here, we used a genome-wide damage mapping method, N -methylpurine-sequencing (NMP-seq), and characterized alkylation damage distribution and BER at TF binding sites in yeast cells treated with the alkylating agent methyl methanesulfonate (MMS). Our data show that alkylation damage formation was mainly suppressed at the binding sites of yeast TFs ARS binding factor 1 (Abf1) and rDNA enhancer binding protein 1 (Reb1), but individual hotspots with elevated damage levels were also found. Additionally, Abf1 and Reb1 binding strongly inhibits BER in vivo and in vitro, causing slow repair both within the core motif and its adjacent DNA. Repair of ultraviolet (UV) damage by nucleotide excision repair (NER) was also inhibited by TF binding. Interestingly, TF binding inhibits a larger DNA region for NER relative to BER. The observed effects are caused by the TF–DNA interaction, because damage formation and BER can be restored by depletion of Abf1 or Reb1 protein from the nucleus. Thus, our data reveal that TF binding significantly modulates alkylation base damage formation and inhibits repair by the BER pathway. The interplay between base damage formation and BER may play an important role in affecting mutation frequency in gene regulatory regions. 

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2. Mouse models to explore the biological and organismic role of DNA polymerase beta

   https://doi.org/10.1002/em.22593  

   Sobol, Robert W. ( April 2024 , Environmental and Molecular Mutagenesis)

   Gene knock‐out (KO) mouse models for DNA polymerase beta (Polβ) revealed that loss of Polβ leads to neonatal lethality, highlighting the critical organismic role for this DNA polymerase. While biochemical analysis and gene KO cell lines have confirmed its biochemical role in base excision repair and in TET‐mediated demethylation, more long‐lived mouse models continue to be developed to further define its organismic role. ThePolb‐KO mouse was the first of the Cre‐mediated tissue‐specific KO mouse models. This technology was exploited to investigate roles for Polβ in V(D)J recombination (variable‐diversity‐joining rearrangement), DNA demethylation, gene complementation, SPO11‐induced DNA double‐strand break repair, germ cell genome stability, as well as neuronal differentiation, susceptibility to genotoxin‐induced DNA damage, and cancer onset. The revolution in knock‐in (KI) mouse models was made possible by CRISPR/cas9‐mediated gene editing directly in C57BL/6 zygotes. This technology has helped identify phenotypes associated with germline or somatic mutants of Polβ. Such KI mouse models have helped uncover the importance of key Polβ active site residues or specific Polβ enzyme activities, such as thePolb^Y265Cmouse that develops lupus symptoms. More recently, we have used this KI technology to mutate thePolbgene with two codon changes, yielding thePolb^L301R/V303Rmouse. In this KI mouse model, the expressed Polβ protein cannot bind to its obligate heterodimer partner, Xrcc1. Although the expressed mutant Polβ protein is proteolytically unstable and defective in recruitment to sites of DNA damage, the homozygousPolb^L301R/V303Rmouse is viable and fertile, yet small in stature. We expect that this and additional targeted mouse models under development are poised to reveal new biological and organismic roles for Polβ.

    

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3. Inspiring basic and applied research in genome integrity mechanisms: Dedication to Samuel H. Wilson

   https://doi.org/10.1002/em.22595  

   Yan, Shan ; Gaddameedhi, Shobhan ; Sobol, Robert W. ( April 2024 , Environmental and Molecular Mutagenesis)

   This Special Issue (SI) of Environmental and Molecular Mutagenesis (EMM), entitled “Inspiring Basic and Applied Research in Genome Integrity Mechanisms,” is to update the community on recent findings and advances on genome integrity mechanisms with emphasis on their importance for basic and environmental health sciences. This SI includes two research articles, one brief research communication, and four reviews that highlight cutting edge research findings and perspectives, from both established leaders and junior trainees, on DNA repair mechanisms. In particular, the authors provided an updated understanding on several distinct enzymes (e.g., DNA polymerase beta, DNA polymerase theta, DNA glycosylase NEIL2) and the associated molecular mechanisms in base excision repair, nucleotide excision repair, and microhomology‐mediated end joining of double‐strand breaks. In addition, genome‐wide sequencing analysis or site‐specific mutational signature analysis of DNA lesions from environmental mutagens (e.g., UV light and aflatoxin) provide further characterization and sequence context impact of DNA damage and mutations. This SI is dedicated to the legacy of Dr. Samuel H. Wilson from the U.S. National Institute of Environmental Health Sciences at the National Institutes of Health.

    

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4. ETS transcription factors induce a unique UV damage signature that drives recurrent mutagenesis in melanoma

   https://doi.org/10.1038/s41467-018-05064-0  

   Mao, Peng ; Brown, Alexander J. ; Esaki, Shingo ; Lockwood, Svetlana ; Poon, Gregory M. K. ; Smerdon, Michael J. ; Roberts, Steven A. ; Wyrick, John J. ( July 2018 , Nature Communications)

   Recurrent mutations are frequently associated with transcription factor (TF) binding sites (TFBS) in melanoma, but the mechanism driving mutagenesis at TFBS is unclear. Here, we use a method called CPD-seq to map the distribution of UV-induced cyclobutane pyrimidine dimers (CPDs) across the human genome at single nucleotide resolution. Our results indicate that CPD lesions are elevated at active TFBS, an effect that is primarily due to E26 transformation-specific (ETS) TFs. We show that ETS TFs induce a unique signature of CPD hotspots that are highly correlated with recurrent mutations in melanomas, despite high repair activity at these sites. ETS1 protein renders its DNA binding targets extremely susceptible to UV damage in vitro, due to binding-induced perturbations in the DNA structure that favor CPD formation. These findings define a mechanism responsible for recurrent mutations in melanoma and reveal that DNA binding by ETS TFs is inherently mutagenic in UV-exposed cells.

    

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5. Synthetic amyloid beta does not induce a robust transcriptional response in innate immune cell culture systems

   https://doi.org/10.1186/s12974-022-02459-1  

   Quiroga, I. Y. ; Cruikshank, A. E. ; Bond, M. L. ; Reed, K. S. M. ; Evangelista, B. A. ; Tseng, J. H. ; Ragusa, J. V. ; Meeker, R. B. ; Won, H. ; Cohen, S. ; et al ( April 2022 , Journal of Neuroinflammation)

   Alzheimer’s disease (AD) is a progressive neurodegenerative disease that impacts nearly 400 million people worldwide. The accumulation of amyloid beta (Aβ) in the brain has historically been associated with AD, and recent evidence suggests that neuroinflammation plays a central role in its origin and progression. These observations have given rise to the theory that Aβ is the primary trigger of AD, and induces proinflammatory activation of immune brain cells (i.e., microglia), which culminates in neuronal damage and cognitive decline. To test this hypothesis, many in vitro systems have been established to study Aβ-mediated activation of innate immune cells. Nevertheless, the transcriptional resemblance of these models to the microglia in the AD brain has never been comprehensively studied on a genome-wide scale.

   We used bulk RNA-seq to assess the transcriptional differences between in vitro cell types used to model neuroinflammation in AD, including several established, primary and iPSC-derived immune cell lines (macrophages, microglia and astrocytes) and their similarities to primary cells in the AD brain. We then analyzed the transcriptional response of these innate immune cells to synthetic Aβ or LPS and INFγ.

   We found that human induced pluripotent stem cell (hIPSC)-derived microglia (IMGL) are the in vitro cell model that best resembles primary microglia. Surprisingly, synthetic Aβ does not trigger a robust transcriptional response in any of the cellular models analyzed, despite testing a wide variety of Aβ formulations, concentrations, and treatment conditions. Finally, we found that bacterial LPS and INFγ activate microglia and induce transcriptional changes that resemble many, but not all, aspects of the transcriptomic profiles of disease associated microglia (DAM) present in the AD brain.

   These results suggest that synthetic Aβ treatment of innate immune cell cultures does not recapitulate transcriptional profiles observed in microglia from AD brains. In contrast, treating IMGL with LPS and INFγ induces transcriptional changes similar to those observed in microglia detected in AD brains.

    

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