Your search keyword '"Miller, Kyle M."' showing total 8 results

1. Single-Cell Analysis of Histone Acetylation Dynamics at Replication Forks Using PLA and SIRF.

Author

Lee SY, Kim JJ, and Miller KM

Subjects

Acetylation, Lysine metabolism, Single-Cell Analysis, DNA metabolism, Histones metabolism, DNA Replication

Abstract

Genome integrity is constantly challenged by various processes including DNA damage, structured DNA, transcription, and DNA-protein crosslinks. During DNA replication, active replication forks that encounter these obstacles can result in their stalling and collapse. Accurate DNA replication requires the ability of forks to navigate these threats, which is aided by DNA repair proteins. Histone acetylation participates in this process through an ability to signal and recruit proteins to regions of replicating DNA. For example, the histone acetyltransferase PCAF promotes the recruitment of the DNA repair factors MRE11 and EXO1 to stalled forks by acetylating histone H4 at lysine 8 (H4K8ac). These highly dynamic processes can be detected and analyzed using a modified proximity ligation assay (PLA) method, known as SIRF (in situ protein interactions with nascent DNA replication forks). This single-cell assay combines PLA with EdU-coupled Click-iT chemistry reactions and fluorescence microscopy to detect these interactions at sites of replicating DNA. Here we provide a detailed protocol utilizing SIRF that detects the HAT PCAF and histone acetylation at replication forks. This technique provides a robust methodology to determine protein recruitment and modifications at the replication fork with single-cell resolution., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

2. PCAF-Mediated Histone Acetylation Promotes Replication Fork Degradation by MRE11 and EXO1 in BRCA-Deficient Cells.

Author

Kim JJ, Lee SY, Choi JH, Woo HG, Xhemalce B, and Miller KM

Subjects

Acetylation drug effects, Amino Acid Sequence, Ataxia Telangiectasia Mutated Proteins metabolism, BRCA1 Protein metabolism, BRCA2 Protein metabolism, Breast Neoplasms genetics, Cell Line, Tumor, Female, Gene Expression Regulation, Neoplastic drug effects, Humans, Lysine metabolism, Models, Biological, Mutation genetics, Phosphorylation drug effects, Phosphoserine metabolism, Poly(ADP-ribose) Polymerase Inhibitors pharmacology, Protein Binding drug effects, p300-CBP Transcription Factors chemistry, p300-CBP Transcription Factors genetics, BRCA1 Protein deficiency, BRCA2 Protein deficiency, DNA Repair Enzymes metabolism, DNA Replication drug effects, Exodeoxyribonucleases metabolism, Histones metabolism, MRE11 Homologue Protein metabolism, p300-CBP Transcription Factors metabolism

Abstract

Stabilization of stalled replication forks is a prominent mechanism of PARP (Poly(ADP-ribose) Polymerase) inhibitor (PARPi) resistance in BRCA-deficient tumors. Epigenetic mechanisms of replication fork stability are emerging but remain poorly understood. Here, we report the histone acetyltransferase PCAF (p300/CBP-associated) as a fork-associated protein that promotes fork degradation in BRCA-deficient cells by acetylating H4K8 at stalled replication forks, which recruits MRE11 and EXO1. A H4K8ac binding domain within MRE11/EXO1 is required for their recruitment to stalled forks. Low PCAF levels, which we identify in a subset of BRCA2-deficient tumors, stabilize stalled forks, resulting in PARPi resistance in BRCA-deficient cells. Furthermore, PCAF activity is tightly regulated by ATR (ataxia telangiectasia and Rad3-related), which phosphorylates PCAF on serine 264 (S264) to limit its association and activity at stalled forks. Our results reveal PCAF and histone acetylation as critical regulators of fork stability and PARPi responses in BRCA-deficient cells, which provides key insights into targeting BRCA-deficient tumors and identifying epigenetic modulators of chemotherapeutic responses., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

3. Semi-conservative DNA replication through telomeres requires Taz1.

Author

Miller KM, Rog O, and Cooper JP

Subjects

DNA-Binding Proteins deficiency, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Kinetics, Schizosaccharomyces pombe Proteins genetics, Shelterin Complex, Telomerase deficiency, Telomerase genetics, Telomerase metabolism, Telomere genetics, Telomere-Binding Proteins deficiency, Telomere-Binding Proteins genetics, Templates, Genetic, DNA Replication, Schizosaccharomyces genetics, Schizosaccharomyces metabolism, Schizosaccharomyces pombe Proteins metabolism, Telomere metabolism, Telomere-Binding Proteins metabolism

Abstract

Telomere replication is achieved through the combined action of the conventional DNA replication machinery and the reverse transcriptase, telomerase. Telomere-binding proteins have crucial roles in controlling telomerase activity; however, little is known about their role in controlling semi-conservative replication, which synthesizes the bulk of telomeric DNA. Telomere repeats in the fission yeast Schizosaccharomyces pombe are bound by Taz1, a regulator of diverse telomere functions. It is generally assumed that telomere-binding proteins impede replication fork progression. Here we show that, on the contrary, Taz1 is crucial for efficient replication fork progression through the telomere. Using two-dimensional gel electrophoresis, we find that loss of Taz1 leads to stalled replication forks at telomeres and internally placed telomere sequences, regardless of whether the telomeric G-rich strand is replicated by leading- or lagging-strand synthesis. In contrast, the Taz1-interacting protein Rap1 is dispensable for efficient telomeric fork progression. Upon loss of telomerase, taz1Delta telomeres are lost precipitously, suggesting that maintenance of taz1Delta telomere repeats cannot be sustained through semi-conservative replication. As the human telomere proteins TRF1 and TRF2 are Taz1 orthologues, we predict that one or both of the human TRFs may orchestrate fork passage through human telomeres. Stalled forks at dysfunctional human telomeres are likely to accelerate the genomic instability that drives tumorigenesis.

Published

2006

4. The nucleosome: orchestrating DNA damage signaling and repair within chromatin1.

Author

Agarwal, Poonam and Miller, Kyle M.

Subjects

*DNA damage, *MOLECULAR structure of chromatin, *DNA repair, *GENETIC transcription, *DNA replication, *CHEMICAL modification of proteins, *HISTONES

Abstract

DNA damage occurs within the chromatin environment, which ultimately participates in regulating DNA damage response (DDR) pathways and repair of the lesion. DNA damage activates a cascade of signaling events that extensively modulates chromatin structure and organization to coordinate DDR factor recruitment to the break and repair, whilst also promoting the maintenance of normal chromatin functions within the damaged region. For example, DDR pathways must avoid conflicts between other DNA-based processes that function within the context of chromatin, including transcription and replication. The molecular mechanisms governing the recognition, target specificity, and recruitment of DDR factors and enzymes to the fundamental repeating unit of chromatin, i.e., the nucleosome, are poorly understood. Here we present our current view of how chromatin recognition by DDR factors is achieved at the level of the nucleosome. Emerging evidence suggests that the nucleosome surface, including the nucleosome acidic patch, promotes the binding and activity of several DNA damage factors on chromatin. Thus, in addition to interactions with damaged DNA and histone modifications, nucleosome recognition by DDR factors plays a key role in orchestrating the requisite chromatin response to maintain both genome and epigenome integrity. [ABSTRACT FROM AUTHOR]

Published

2016

5. The nucleosome: orchestrating DNA damage signaling and repair within chromatin1.

Author

Agarwal, Poonam and Miller, Kyle M.

Subjects

DNA damage, MOLECULAR structure of chromatin, DNA repair, GENETIC transcription, DNA replication, CHEMICAL modification of proteins, HISTONES

Abstract

Copyright of Biochemistry & Cell Biology is the property of Canadian Science Publishing and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2016

6. Transcriptionally active chromatin recruits homologous recombination at DNA double-strand breaks.

Author

Aymard, François, Bugler, Beatrix, Schmidt, Christine K, Guillou, Emmanuelle, Caron, Pierre, Briois, Sébastien, Iacovoni, Jason S, Daburon, Virginie, Miller, Kyle M, Jackson, Stephen P, and Legube, Gaëlle

Subjects

CHROMATIN assembly factors, HUMAN chromatin, BIOCHEMICAL mechanism of action, DNA repair, DNA replication, GENE rearrangement, IMMUNOPRECIPITATION

Abstract

Although both homologous recombination (HR) and nonhomologous end joining can repair DNA double-strand breaks (DSBs), the mechanisms by which one of these pathways is chosen over the other remain unclear. Here we show that transcriptionally active chromatin is preferentially repaired by HR. Using chromatin immunoprecipitation-sequencing (ChIP-seq) to analyze repair of multiple DSBs induced throughout the human genome, we identify an HR-prone subset of DSBs that recruit the HR protein RAD51, undergo resection and rely on RAD51 for efficient repair. These DSBs are located in actively transcribed genes and are targeted to HR repair via the transcription elongation-associated mark trimethylated histone H3 K36. Concordantly, depletion of SETD2, the main H3 K36 trimethyltransferase, severely impedes HR at such DSBs. Our study thereby demonstrates a primary role in DSB repair of the chromatin context in which a break occurs. [ABSTRACT FROM AUTHOR]

Published

2014

7. Sumoylation of RecQ Helicase Controls the Fate of Dysfunctional Telomeres

Author

Rog, Ofer, Miller, Kyle M., Ferreira, Miguel Godinho, and Cooper, Julia Promisel

Subjects

*DNA helicases, *TELOMERES, *DNA repair, *DNA damage, *DNA replication, *GENETIC mutation

Abstract

Summary: Genome stability depends upon the RecQ helicases, which are conserved from bacteria to man, but little is known about how their myriad activities are regulated. Fission yeast lacking the telomere protein Taz1 (mammalian TRF1/TRF2 ortholog) lose many hallmarks of telomeres, including accurate replication and local protection from DNA repair reactions. Here we show that the RecQ homolog, Rqh1, is sumoylated. Surprisingly, Rqh1 acts on taz1Δ telomeres in a deleterious way, promoting telomere breakage and entanglement. Mutation of Rqh1 sumoylation sites rescues taz1Δ cells from these hazards without dramatically affecting nontelomeric Rqh1 functions. The prominence of Rqh1 in the etiology of several different telomere defects supports the idea that they originate from a common underlying lesion—aberrant processing of the stalled telomeric replication forks that accumulate in the absence of Taz1. Our work underscores the principle that RecQ helicases are “double-edged swords” whose activity, while necessary for maintaining genome-wide stability, must be vigilantly controlled. [Copyright &y& Elsevier]

Published

2009

8. Non-canonical DNA/RNA structures during Transcription-Coupled Double-Strand Break Repair: Roadblocks or Bona fide repair intermediates?

Author

Puget, Nadine, Miller, Kyle M., and Legube, Gaëlle

Subjects

*QUADRUPLEX nucleic acids, *DNA structure, *DNA replication, *DOUBLE-strand DNA breaks, *DNA, *RNA, *NUCLEIC acids

Abstract

Although long overlooked, it is now well understood that DNA does not systematically assemble into a canonical double helix, known as B-DNA, throughout the entire genome but can also accommodate other structures including DNA hairpins, G-quadruplexes and RNA:DNA hybrids. Notably, these non-canonical DNA structures form preferentially at transcriptionally active loci. Acting as replication roadblocks and being targeted by multiple machineries, these structures weaken the genome and render it prone to damage, including DNA double-strand breaks (DSB). In addition, secondary structures also further accumulate upon DSB formation. Here we discuss the potential functions of pre-existing or de novo formed nucleic acid structures, as bona fide repair intermediates or repair roadblocks, especially during Transcription-Coupled DNA Double-Strand Break repair (TC-DSBR), and provide an update on the specialized protein complexes displaying the ability to remove these structures to safeguard genome integrity. [ABSTRACT FROM AUTHOR]

Published

2019