scholarly journals The Functional Consequences of Eukaryotic Topoisomerase 1 Interaction with G-Quadruplex DNA

Genes ◽  
2020 ◽  
Vol 11 (2) ◽  
pp. 193
Author(s):  
Alexandra Berroyer ◽  
Nayun Kim
Keyword(s):  
Topoisomerase I ◽  
Genome Instability ◽  
Strand Break ◽  
Dna Topology ◽  
Single Strand Break ◽  
Dna Structures ◽  
G4 Dna ◽  
G Quadruplex

Topoisomerase I in eukaryotic cells is an important regulator of DNA topology. Its catalytic function is to remove positive or negative superhelical tension by binding to duplex DNA, creating a reversible single-strand break, and finally religating the broken strand. Proper maintenance of DNA topological homeostasis, in turn, is critically important in the regulation of replication, transcription, DNA repair, and other processes of DNA metabolism. One of the cellular processes regulated by the DNA topology and thus by Topoisomerase I is the formation of non-canonical DNA structures. Non-canonical or non-B DNA structures, including the four-stranded G-quadruplex or G4 DNA, are potentially pathological in that they interfere with replication or transcription, forming hotspots of genome instability. In this review, we first describe the role of Topoisomerase I in reducing the formation of non-canonical nucleic acid structures in the genome. We further discuss the interesting recent discovery that Top1 and Top1 mutants bind to G4 DNA structures in vivo and in vitro and speculate on the possible consequences of these interactions.

scholarly journals E. coli Rep helicase and RecA recombinase unwind G4 DNA and are important for resistance to G4-stabilizing ligands

2020 ◽  
Vol 48 (12) ◽  
pp. 6640-6653 ◽  
Author(s):  
Tapas Paul ◽  
Andrew F Voter ◽  
Rachel R Cueny ◽  
Momčilo Gavrilov ◽  
Taekjip Ha ◽  
...  
Keyword(s):  
Atp Hydrolysis ◽  
Cellular Toxicity ◽  
Dna Structures ◽  
E Coli ◽  
G4 Dna ◽  
G Quadruplex ◽  
Physical Barriers ◽  
Stabilizing Ligands

Abstract G-quadruplex (G4) DNA structures can form physical barriers within the genome that must be unwound to ensure cellular genomic integrity. Here, we report unanticipated roles for the Escherichia coli Rep helicase and RecA recombinase in tolerating toxicity induced by G4-stabilizing ligands in vivo. We demonstrate that Rep and Rep-X (an enhanced version of Rep) display G4 unwinding activities in vitro that are significantly higher than the closely related UvrD helicase. G4 unwinding mediated by Rep involves repetitive cycles of G4 unfolding and refolding fueled by ATP hydrolysis. Rep-X and Rep also dislodge G4-stabilizing ligands, in agreement with our in vivo G4-ligand sensitivity result. We further demonstrate that RecA filaments disrupt G4 structures and remove G4 ligands in vitro, consistent with its role in countering cellular toxicity of G4-stabilizing ligands. Together, our study reveals novel genome caretaking functions for Rep and RecA in resolving deleterious G4 structures.

scholarly journals Substrate Specificity of Tyrosyl-DNA Phosphodiesterase I (Tdp1)

2005 ◽  
Vol 280 (23) ◽  
pp. 22029-22035 ◽  
Author(s):  
Amy C. Raymond ◽  
Bart L. Staker ◽  
Alex B. Burgin
Keyword(s):  
Mammalian Cells ◽  
Topoisomerase I ◽  
Strand Break ◽  
Dna Lesions ◽  
Single Strand ◽  
Binding Properties ◽  
Single Strand Break ◽  
Single Strand Break Repair

Tyrosyl-DNA phosphodiesterase I (Tdp1) hydrolyzes 3′-phosphotyrosyl bonds to generate 3′-phosphate DNA and tyrosine in vitro. Tdp1 is involved in the repair of DNA lesions created by topoisomerase I, although the in vivo substrate is not known. Here we study the kinetic and binding properties of human Tdp1 (hTdp1) to identify appropriate 3′-phosphotyrosyl DNA substrates. Genetic studies argue that Tdp1 is involved in double and single strand break repair pathways; however, x-ray crystal structures suggest that Tdp1 can only bind single strand DNA. Separate kinetic and binding experiments show that hTdp1 has a preference for single-stranded and blunt-ended duplex substrates over nicked and tailed duplex substrate conformations. Based on these results, we present a new model to explain Tdp1/DNA binding properties. These results suggest that Tdp1 only acts upon double strand breaks in vivo, and the roles of Tdp1 in yeast and mammalian cells are discussed.

scholarly journals G-quadruplex DNA drives genomic instability and represents a targetable molecular abnormality in ATRX-deficient malignant glioma

2018 ◽  
Author(s):  
Yuxiang Wang ◽  
Jie Yang ◽  
Wei Wu ◽  
Rachna Shah ◽  
Carla Danussi ◽  
...  
Keyword(s):  
Dna Damage ◽  
Malignant Glioma ◽  
Model Systems ◽  
Copy Number Alterations ◽  
Molecular Alteration ◽  
Quadruplex Dna ◽  
G4 Dna ◽  
G Quadruplex

AbstractMutational inactivation of ATRX (α-thalassemia mental retardation X-linked) represents a defining molecular alteration in large subsets of malignant glioma. Yet the pathogenic consequences of ATRX deficiency remain unclear, as do tractable mechanisms for its therapeutic targeting. Here we report that ATRX loss in isogenic glioma model systems induces replication stress and DNA damage by way of G-quadruplex (G4) DNA secondary structure. Moreover, these effects are associated with the acquisition of disease-relevant copy number alterations over time. We then demonstrate, both in vitro and in vivo, that ATRX deficiency selectively enhances DNA damage and cell death following chemical G4 stabilization. Finally, we show that G4 stabilization synergizes with other DNA-damaging therapies, including ionizing radiation, in the ATRX-deficient context. Our findings reveal novel pathogenic mechanisms driven by ATRX deficiency in glioma, while also pointing to tangible strategies for drug development.

scholarly journals Helicases FANCJ, RTEL1 and BLM Act on Guanine Quadruplex DNA in Vivo

Genes ◽  
2019 ◽  
Vol 10 (11) ◽  
pp. 870 ◽  
Author(s):  
Peter Lansdorp ◽  
Niek van Wietmarschen
Keyword(s):  
Gene Expression ◽  
Genome Stability ◽  
Cell Function ◽  
Historical Context ◽  
Telomere Maintenance ◽  
Dna Structures ◽  
G4 Dna ◽  
Guanine Quadruplex

Guanine quadruplex (G4) structures are among the most stable secondary DNA structures that can form in vitro, and evidence for their existence in vivo has been steadily accumulating. Originally described mainly for their deleterious effects on genome stability, more recent research has focused on (potential) functions of G4 structures in telomere maintenance, gene expression, and other cellular processes. The combined research on G4 structures has revealed that properly regulating G4 DNA structures in cells is important to prevent genome instability and disruption of normal cell function. In this short review we provide some background and historical context of our work resulting in the identification of FANCJ, RTEL1 and BLM as helicases that act on G4 structures in vivo. Taken together these studies highlight important roles of different G4 DNA structures and specific G4 helicases at selected genomic locations and telomeres in regulating gene expression and maintaining genome stability.

scholarly journals Human Rev1 polymerase disrupts G-quadruplex DNA

2013 ◽  
Vol 42 (5) ◽  
pp. 3272-3285 ◽  
Author(s):  
Sarah Eddy ◽  
Amit Ketkar ◽  
Maroof K. Zafar ◽  
Leena Maddukuri ◽  
Jeong-Yun Choi ◽  
...  
Keyword(s):  
Genome Maintenance ◽  
Quadruplex Dna ◽  
Dna Structures ◽  
G4 Dna ◽  
G Quadruplex ◽  
Steady State Rate ◽  
Dna Substrates ◽  
Successful Replication ◽  
Y Family

Abstract The Y-family DNA polymerase Rev1 is required for successful replication of G-quadruplex DNA (G4 DNA) in higher eukaryotes. Here we show that human Rev1 (hRev1) disrupts G4 DNA structures and prevents refolding in vitro. Nucleotidyl transfer by hRev1 is not necessary for mechanical unfolding to occur. hRev1 binds G4 DNA substrates with Kd,DNA values that are 4–15-fold lower than those of non-G4 DNA substrates. The pre-steady-state rate constant of deoxycytidine monophosphate (dCMP) insertion opposite the first tetrad-guanine by hRev1 is ∼56% as fast as that observed for non-G4 DNA substrates. Thus, hRev1 can promote fork progression by either dislodging tetrad guanines to unfold the G4 DNA, which could assist in extension by other DNA polymerases, or hRev1 can prevent refolding of G4 DNA structures. The hRev1 mechanism of action against G-quadruplexes helps explain why replication progress is impeded at G4 DNA sites in Rev1-deficient cells and illustrates another unique feature of this enzyme with important implications for genome maintenance.

scholarly journals Mammalian CST averts replication failure by preventing G-quadruplex accumulation

2018 ◽  
Author(s):  
Yang Liu ◽  
Miaomiao Zhang ◽  
Bing Wang ◽  
Yingnan Xiao ◽  
Tingfang Li ◽  
...  
Keyword(s):  
Replication Fork ◽  
Genome Integrity ◽  
G4 Dna ◽  
Genome Wide ◽  
G Quadruplex ◽  
Preferential Loss ◽  
Telomere Replication ◽  
Lagging Strand

AbstractHuman CST (CTC1-STN1-TEN1) is an RPA-like complex that associates with G-rich single-strand DNA and helps resolve replication problems both at telomeres and genome-wide. We previously showed that CST binds and disrupts G-quadruplex (G4) DNA in vitro, suggesting that CST may prevent in vivo blocks to replication by resolving G4 structures. Here, we demonstrate that CST binds and unfolds G4 with similar efficiency to RPA. In cells, CST is recruited to telomeric and non-telomeric chromatin upon G4 stabilization. STN1 depletion increases G4 accumulation and slows bulk genomic DNA replication. At telomeres, combined STN1 depletion and G4 stabilization causes multi-telomere FISH signals and telomere loss, hallmarks of deficient telomere duplex replication. Strand-specific telomere FISH indicates preferential loss of C-strand DNA while analysis of BrdU uptake during leading and lagging-strand telomere replication shows preferential under-replication of lagging telomeres. Together these results indicate a block to Okazaki fragment synthesis. Overall, our findings indicate a novel role for CST in maintaining genome integrity through resolution of G4 structures both ahead of the replication fork and on the lagging strand template.

scholarly journals The Relevance of G-Quadruplexes for DNA Repair

2021 ◽  
Vol 22 (22) ◽  
pp. 12599
Author(s):  
Rebecca Linke ◽  
Michaela Limmer ◽  
Stefan Juranek ◽  
Annkristin Heine ◽  
Katrin Paeschke
Keyword(s):  
Dna Damage ◽  
Dna Repair ◽  
Genome Stability ◽  
Genome Instability ◽  
Genetic Disorders ◽  
Telomere Maintenance ◽  
Dna Structures ◽  
G4 Dna ◽  
G Quadruplex ◽  
Repair Pathways

DNA molecules can adopt a variety of alternative structures. Among these structures are G-quadruplex DNA structures (G4s), which support cellular function by affecting transcription, translation, and telomere maintenance. These structures can also induce genome instability by stalling replication, increasing DNA damage, and recombination events. G-quadruplex-driven genome instability is connected to tumorigenesis and other genetic disorders. In recent years, the connection between genome stability, DNA repair and G4 formation was further underlined by the identification of multiple DNA repair proteins and ligands which bind and stabilize said G4 structures to block specific DNA repair pathways. The relevance of G4s for different DNA repair pathways is complex and depends on the repair pathway itself. G4 structures can induce DNA damage and block efficient DNA repair, but they can also support the activity and function of certain repair pathways. In this review, we highlight the roles and consequences of G4 DNA structures for DNA repair initiation, processing, and the efficiency of various DNA repair pathways.

scholarly journals High Affinity binding of Yeast Nucleolin Nsr1 to Co-transcriptionally Formed G4 DNA Obstructs Replication and Elevates Genome Instability

2019 ◽  
Author(s):  
Shivani Singh ◽  
Alexandra Berroyer ◽  
Minseon Kim ◽  
Nayun Kim
Keyword(s):  
Dna Binding ◽  
Genome Instability ◽  
Binding Protein ◽  
Dna Binding Protein ◽  
Yeast Genome ◽  
Stable Complex ◽  
High Affinity ◽  
G4 Dna ◽  
G Quadruplex

ABSTRACTA significant increase in genome instability is associated with the conformational shift of a guanine-run-containing DNA strand into the four-stranded G-quadruplex (G4) DNA. The mechanism underlying the recombination and genome rearrangements following the formation of G4 DNA in vivo has been difficult to elucidate but has become better clarified by the identification and functional characterization of several key G4 DNA-binding proteins. Mammalian nucleolin NCL is a highly specific G4 DNA-binding protein with a well-defined role in the transcriptional regulation of genes with associated G4 DNA-forming sequence motifs at their promoters. The consequence of the in vivo interaction between G4 DNA and nucleolin in respect to the genome instability has not been previously investigated. We show here that G4 DNA-binding is a conserved function in the yeast nucleolin Nsr1. Furthermore, we demonstrate that the Nsr1-G4 DNA complex formation results in replication obstruction and is a major factor in inducing the genome instability associated with the co-transcriptionally formed G4 DNA in the yeast genome. The G4-associated genome instability and the G4 DNA-binding in vivo requires the arginine-glycine-glycine (RGG) repeats located at the C-terminus of the Nsr1 protein. Nsr1 with the deletion of RGG domain supports normal cell growth and is sufficient for its pre-rRNA processing function. However, the truncation of RGG domain of Nsr1 significantly weakens its interaction with G4 DNA in vitro and in vivo and restores unhindered replication, overall resulting in a sharp reduction in the G4-associated genome instability. Our data suggest that the interaction between Nsr1 with the intact RGG repeats and G4 DNA impairs genome stability by precluding the access of G4-resolving proteins and obstructing replication.AUTHOR SUMMARYGenome instability is uniquely elevated at sequences containing multiple runs of guanines, which can fold into the unusual, four-stranded G-quadruplex (G4) DNA. In this study, we report a novel finding that a highly conserved G4 DNA binding protein Nsr1 can elevate the rate of recombination and chromosomal rearrangement occurring at a G4 DNA-forming sequence in the genome of Saccharomyces cerevisiae. The elevated genome instability requires the C-terminally located RGG domain of Nsr1, which supports the high-affinity interaction between the protein and G4 DNA. The connection between G4-specific genome instability and the function of Nsr1 to form stable complex with G4 DNA led to the hypothesis that the high-affinity Nsr1-G4 DNA complexes can become a barrier to replication. We demonstrate here that the presence of Nsr1 in fact slows the replication past a G4 DNA-containing genomic site and that the RGG domain is required to facilitate such replication block.

scholarly journals Crystal Structures of Poly(ADP-ribose) Polymerase-1 (PARP-1) Zinc Fingers Bound to DNA

2011 ◽  
Vol 286 (12) ◽  
pp. 10690-10701 ◽  
Author(s):  
Marie-France Langelier ◽  
Jamie L. Planck ◽  
Swati Roy ◽  
John M. Pascal
Keyword(s):  
Crystal Structures ◽  
Zinc Fingers ◽  
Dna Interaction ◽  
Strand Break ◽  
Structural Basis ◽  
Dna Structures ◽  
Parp 1 ◽  
Nucleotide Bases

Poly(ADP-ribose) polymerase-1 (PARP-1) has two homologous zinc finger domains, Zn1 and Zn2, that bind to a variety of DNA structures to stimulate poly(ADP-ribose) synthesis activity and to mediate PARP-1 interaction with chromatin. The structural basis for interaction with DNA is unknown, which limits our understanding of PARP-1 regulation and involvement in DNA repair and transcription. Here, we have determined crystal structures for the individual Zn1 and Zn2 domains in complex with a DNA double strand break, providing the first views of PARP-1 zinc fingers bound to DNA. The Zn1-DNA and Zn2-DNA structures establish a novel, bipartite mode of sequence-independent DNA interaction that engages a continuous region of the phosphodiester backbone and the hydrophobic faces of exposed nucleotide bases. Biochemical and cell biological analysis indicate that the Zn1 and Zn2 domains perform distinct functions. The Zn2 domain exhibits high binding affinity to DNA compared with the Zn1 domain. However, the Zn1 domain is essential for DNA-dependent PARP-1 activity in vitro and in vivo, whereas the Zn2 domain is not strictly required. Structural differences between the Zn1-DNA and Zn2-DNA complexes, combined with mutational and structural analysis, indicate that a specialized region of the Zn1 domain is re-configured through the hydrophobic interaction with exposed nucleotide bases to initiate PARP-1 activation.

G-quadruplex unwinding helicases and their function in vivo

2017 ◽  
Vol 45 (5) ◽  
pp. 1173-1182 ◽  
Author(s):  
Markus Sauer ◽  
Katrin Paeschke
Keyword(s):  
Dna Replication ◽  
Genome Instability ◽  
Evolutionary Conservation ◽  
Telomere Maintenance ◽  
Cellular Functions ◽  
G Quadruplex

The concept that G-quadruplex (G4) structures can form within DNA or RNA in vitro has been long known and extensively discussed. In recent years, accumulating evidences imply that G-quadruplex structures form in vivo. Initially, inefficient regulation of G-quadruplex structures was mainly associated with genome instability. However, due to the location of G-quadruplex motifs and their evolutionary conservation, different cellular functions of these structures have been postulated (e.g. in telomere maintenance, DNA replication, transcription, and translation). Regardless of their function, efficient and controlled formation and unwinding are very important, because ‘mis’-regulated G-quadruplex structures are detrimental for a given process, causing genome instability and diseases. Several helicases have been shown to target and regulate specific G-quadruplex structures. This mini-review focuses on the biological consequences of G4 disruption by different helicases in vivo.

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