Estradamacpherson6508

The methods include real-time quantitation of kinetics of DNA unwinding-synthesis by a coupled helicase-DNA polymerase complex, a 2-aminopurine fluorescence-based assay to map the precise positions of helicase and DNA polymerase with respect to the replication fork junction, and a radiometric assay to study the coupling of DNA polymerase, exonuclease, and helicase activities during processive leading strand DNA synthesis. These methods are presented here with bacteriophage T7 replication proteins as an example but can be applied to other systems with appropriate modifications.Formation of protein/nucleic acid complexes is essential for life. From DNA replication and repair to transcription and translation, myriad different proteins bind nucleic acids to execute their essential cellular functions. Our understanding of the mechanisms underlying recognition and processing of nucleic acids can be greatly informed by mapping protein domains and residues that form interfaces with their DNA or RNA targets. Here we describe a crosslinking protocol in which the unnatural amino acid p-benzoyl-l-phenylalanine (Bpa) integrated at selected sites within the PriA DNA helicase is used to map surfaces of the protein that interact with specific positions in a synthetic DNA replication fork in vitro.DNA topoisomerases resolve topological stress by introducing transient single- or double-strand breaks into the DNA duplex. This reaction requires the covalent binding of topoisomerases to DNA while the topological stress is being released. This transient intermediate is known as topoisomerase-covalent complex and represents the target of many anti-cancer drugs. Here, we describe a protocol to quantitatively detect topoisomerase-covalent complexes in vivo, called RADAR (rapid approach to DNA adduct recovery). DNA and protein-DNA covalent complexes are rapidly isolated from cells through chaotropic extraction. After normalization, samples are loaded on a slot blot, and the covalent complexes are detected using specific topoisomerase antibodies. In addition to being fast and robust, this assay produces quantitative results. Consequently, the RADAR assay can be applied to investigate the topoisomerase-covalent complex biology, including the effect of specific topoisomerase inhibitors. Finally, the same assay can be more generally applied to study covalent complexes of other enzymes with DNA.Break-Induced Replication (BIR) is a homologous recombination (HR) pathway that differentiates itself from all other HR pathways by involving extensive DNA synthesis of up to hundreds of kilobases. This DNA synthesis occurs in G2/M arrested cells by a mechanism distinct from regular DNA replication. BIR initiates by strand invasion of a single end of a DNA double-strand break (DSB) followed by extensive D-loop migration. The main replicative helicase Mcm2-7 is dispensable for BIR, however, Pif1 helicase and its PCNA interaction domain are required. Pif1 helicase was shown to be important for extensive repair-specific DNA synthesis at DSB in budding and fission yeasts, flies, and human cells, implicating conservation of the mechanism. Additionally, Mph1 helicase negatively regulates BIR by unwinding migrating D-loops, and Srs2 promotes BIR by eliminating the toxic joint molecules. Here, we describe the methods that address the following questions in studying BIR (i) how to distinguish enzymes needed specifically for BIR from enzymes needed for other HR mechanisms that require short patch DNA synthesis, (ii) what are the phenotypes expected for mutants deficient in extensive synthesis during BIR, (iii) how to follow extensive DNA synthesis during BIR? Methods are described using yeast model organism and wild-type cells are compared side-by-side with Pif1 deficient cells.When a replication fork encounters a nick in the parental DNA, the replisome dissociates and the replication fork structure is lost. This outcome is referred to as replication fork "collapse." Collapsed forks can be highly cytotoxic and mutagenic if not appropriately repaired by the cell. However, the events that occur during and after replication fork collapse are unclear. Here, we describe an in vitro system to induce site specific, strand specific replication fork collapse using Xenopus egg extracts, which contain the full set of DNA replication and repair enzymes. We also describe simple assays to monitor the stability of DNA nicks and the different structures formed during replication fork collapse. This methodology permits detailed mechanistic analysis of collapsed forks in vitro.Single-molecule imaging studies using long linear DNA substrates have revealed unanticipated insights into the dynamics of multi-protein systems. The use of long DNA substrates allows for the study of protein-DNA interactions with observation of the movement and behavior of proteins over distances accessible by fluorescence microscopy. Generalized methods can be exploited to generate and optimize a variety of linear DNA substrates with plasmid DNA as a simple starting point using standard biochemical techniques. Here, we present protocols to produce high-quality plasmid-based 36-kb linear DNA substrates that support DNA replication by the Escherichia coli replisome and that contain chemical lesions at well-defined positions. These substrates can be used to visualize replisome-lesion encounters at the single-molecule level, providing mechanistic details of replisome stalling and dynamics occurring during replication rescue and restart.Helicases function in most biological processes that utilize RNA or DNA nucleic acids including replication, recombination, repair, transcription, splicing, and translation. They are motor proteins that bind ATP and then catalyze hydrolysis to release energy which is transduced for conformational changes. SP-2577 nmr Different conformations correspond to different steps in a process that results in movement of the enzyme along the nucleic acid track in a unidirectional manner. Some helicases such as DEAD-box helicases do not translocate, but these enzymes transduce chemical energy from ATP hydrolysis to unwind secondary structure in DNA or RNA. Some helicases function as monomers while others assemble into defined structures, either dimers or higher order oligomers. Dda helicase from bacteriophage T4 and NS3 helicase domain from the hepatitis C virus are examples of monomeric helicases. These helicases can bind to single-stranded DNA in a manner that appears like train engines on a track. When monomeric helicases align on DNA, the activity of the enzymes increases. Helicase activity can include the rate of duplex unwinding and the total number of base pairs melted during a single binding event or processivity. Dda and NS3h are considered as having low processivity, unwinding fewer than 50 base pairs per binding event. Here, we report fusing two molecules of NS3h molecules together through genetically linking the C-terminus of one molecule to the N-terminus of a second NS3h molecule. We observed increased processivity relative to NS3h possibly arising from the increased probability that at least one of the helicases will completely unwind the DNA prior to dissociation. The dimeric enzyme also binds DNA more like the full-length NS3 helicase. Finally, the dimer can displace streptavidin from biotin-labeled oligonucleotide, whereas monomeric NS3h cannot.The G-rich single-stranded telomere overhang can self-fold into G-quadruplex (G4) structure both in vivo and in vitro. In somatic cells, telomeres shorten progressively due to the end-replication. In stem cells, however, telomeres are replenished by a special enzyme, telomerase which synthesizes single-stranded telomere overhang. The active extension by the telomerase releases G-rich overhang segmentally in 5' to 3' direction as the overhang folds into G4 structure after successive elongation. To replicate such vectorial G4 folding process, we employed a superhelicase, Rep-X to release the G-rich sequence gradually. Using single-molecule assay we demonstrated that the folded conformation achieved by the vectorial folding is inherently different from the post-folding where the entire overhang is allowed to fold at once. In addition, the vectorially folded overhangs are less stable and more accessible to a complementary C-rich strand and the telomere binding protein, POT1 compared to the post-folded state. The higher accessibility may have implications for the facile loading of shelterin proteins after DNA replication.DNA can, in addition to the B-DNA conformation, fold into a variety of additional conformations. Among them are G-quadruplex structures that have gained a lot of attention in recent years. G-quadruplex structures (G4s) are highly stable nucleic acid structures that can fold within DNA and RNA molecules. They form in guanine-rich regions that harbor a specific G4 motif. The three-dimensional structure forms via Hoogsteen hydrogen bonding, where the guanines form hydrogen bonds to each other in order to generate G quartets, which stack in order to become G4 structures. The existence and relevance of G4s was controversial as discussed in the past. However, accumulating data was published that supported the model that G4s form in living cells and importantly support biological processes. G4 formation and unfolding is tightly regulated in vivo. If G4s persist in the cell, they can lead to cellular defects such as genome instability. To avoid G4 accumulation in cells, and by this prevent cellular defect, cells has evolved a variety of proteins, mostly helicases, that efficiently unfold G4 DNA and RNA structures. Here, we describe a detailed protocol to monitor G4 structure unfolding by helicases.G-quadruplexes (G4s) are non-canonical nucleic acid structures that form in G-rich regions of the genome and threaten genome stability by interfering with DNA replication. However, the underlying mechanisms are poorly understood. We have recently found that G4s can stall eukaryotic replication forks by blocking the progression of replicative DNA helicase, CMG. In this paper, we detail the methodology of DNA unwinding assays to investigate the impact of G4s on CMG progression. The method details the purification of recombinantly expressed CMG from the budding yeast, Saccharomyces cerevisiae, purification of synthetic oligonucleotides, and covers various aspects of DNA substrate preparation, reaction setup and result interpretation. The use of synthetic oligonucleotides provides the advantage of allowing to control the formation of G4 structures in DNA substrates. The methods discussed here can be adapted for the study of other DNA helicases and provide a general template for the assembly of DNA substrates with distinct G4 structures.The loading of the MCM replicative helicase onto eukaryotic origins of replication occurs via a sequential, symmetric mechanism. Here, we describe a method to study this multistep reaction using electron microscopy. Tools presented include protein expression and purification protocols, methods to produce asymmetric replication origin substrates and bespoke image processing strategies. DNA templates include recognisable protein roadblocks that help to orient DNA replication factors along a specific origin sequence. Detailed electron microscopy image processing protocols are provided to reposition 2D averages onto the original micrograph for the in silico reconstitution of fully occupied origins of replication. Using these tools, a chemically trapped helicase loading intermediate is observed sliding along origin DNA, showcasing a key feature of the MCM loading mechanism. Although developed to study replicative helicase loading, this method can be employed to investigate the mechanism of other multicomponent biochemical reactions, occurring on a flexible polymeric substrate.