Global ETD Search

1	A single molecule view of FEN1 remarkable substrate recognition, perfect catalysis and regulation Zaher, Manal 05 1900 (has links) DNA replication is one of the most fundamental processes in all living organisms. Its semi-discontinuous nature dictates that the lagging strand is synthesized in short fragments called Okazaki fragments. In eukaryotes, each Okazaki fragment is initiated by an ~ 30-40 nucleotide-long RNA-DNA hybrid primer that is synthesized by Pol α-primase complex. To ensure genomic stability, the RNA primer has to be excised, any misincorporations by Pol α have to be corrected for and finally the resulting nick has to be sealed generating a contiguous strand. This feat is accomplished by a highly coordinated and regulated process called Okazaki fragment maturation. At the center of this process are 5’ nucleases, which are structure-specific nucleases that catalyze the incision of phosphodiester bonds one nucleotide into the 5’ end of ssDNA/dsDNA junctions. Previous structural and biochemical studies have shed some light on the mechanism of FEN1 substrate recognition, its catalysis and regulation. However, many gaps in our understanding of this remarkable nuclease still persist. Moreover, the choice between the short- and long-flap pathways is still elusive. Finally, the mechanism of the coordination among the different enzymatic activities of the polymerase, the nuclease and the ligase during Okazaki fragment maturation is still debatable. In this work, we set out to study FEN1 substrate recognition, catalysis and regulation using single molecule techniques. We show that FEN1 employs a sophisticated substrate recognition mechanism through which it actively distorts the DNA to ~100˚ bent angle. It also displays a remarkable selectivity towards its cognate substrate and avoids off-target substrate by a lock-down mechanism that commits the enzyme for catalysis on cognate substrates while promoting the dissociation of non-cognate substrates. We further characterized FEN1 reaction from substrate binding/bending to product handoff and built a comprehensive kinetic scheme that shows FEN1 releasing its product in two steps. Finally, we uncovered an unprecedented role of FEN1 in the choice between short- and long-flap pathways. FEN1 FRET Okazaki fragment maturation single molecule DNA replication PIFE
2	DEFINING THE ROLE OF LYSINE ACETYLATION IN REGULATING THE FIDELITY OF DNA SYNTHESIS Onyekachi Ebelechukwu Ononye (9732053) 07 January 2021 (has links) Accurate DNA replication is vital for maintaining genomic stability. Consequently, the machinery required to drive this process is designed to ensure the meticulous maintenance of information. However, random misincorporation of errors reduce the fidelity of the DNA and lead to pre-mature aging and age-related disorders such as cancer and neurodegenerative diseases. Some of the incorporated errors are the result of the error prone DNA polymerase alpha (Pol a), which initiates synthesis on both the leading and lagging strand. Lagging strand synthesis acquires an increased number of polymerase a tracks because of the number of Okazaki fragments synthesized per round of the cell cycle (~50 million in mammalian cells). The accumulation of these errors invariably reduces the fidelity of the genome. Previous work has shown that these pol a tracks can be removed by two redundant pathways referred to as the short and long flap pathway. The long flap pathway utilizes a complex network of proteins to remove more of the misincorporated nucleotides than the short flap pathway which mediates the removal of shorter flaps. Lysine acetylation has been reported to modulate the function of the nucleases implicated in flap processing. The cleavage activity of the long flap pathway nuclease, Dna2, is stimulated by lysine acetylation while conversely lysine acetylation of the short flap pathway nuclease, FEN1, inhibits its activity. The major protein players implicated during Okazaki fragment processing (OFP) are known, however, the choice of the processing pathway and its regulation by lysine acetylation of its main players is yet unknown. This dissertation identifies three main findings: 1) <i>Saccharomyces cerevisiae</i> helicase, petite integration frequency (Pif1) is lysine acetylated by Esa1 and deacetylated by Rpd3 regulating its viability and biochemical properties including helicase, binding and ATPase activity ii) the single stranded DNA binding protein, human replication protein A (RPA) is modified by p300 and this modification stimulates its primary binding function and iii) lysine acetylated human RPA directs OFP towards the long flap pathway even for a subset of short flaps. Molecular Biology DNA replication Lysine Acetylation Pif1 Helicase RPA Okazaki fragment Okazaki fragment processing
3	The molecular biology of DNA replication in the archaeon Sulfolobus solfataricus Beattie, Thomas R. January 2012 (has links) DNA replication is essential for the propagation of all living organisms. The ability of a cell to accurately duplicate its entire genome is dependent upon the activity of numerous proteins. Identifying the molecular mechanisms by which these proteins act, and determining how they are physically and functionally coordinated at sites of active DNA replication, is central to understanding this essential cellular process. Archaea possess a DNA replication machinery which is ancestral to the one present in eukaryotes, and thus these organisms serve as simplified model systems for understanding the complexities of eukaryotic DNA replication. This thesis investigates the molecular mechanisms underlying Okazaki fragment maturation in the crenarchaeon Sulfolobus solfataricus, which is essential to the completion of lagging strand DNA replication. Reconstitution of Okazaki fragment maturation in vitro demonstrated that the activities of three enzymes – PolB1, Fen1, and Lig1 – are required for this process in S. solfataricus. Furthermore, it was shown that optimum coordination of their three distinct activities is dependent on the ability of PolB1, Fen1 and Lig1 to simultaneously interact with a single PCNA ring, providing evidence for a mechanism of multi-enzyme coordination which may be universally employed by DNA sliding clamp proteins. The importance of protein flexibility in the accommodation of multiple proteins around a single PCNA was also investigated. Finally, the physical coordination of one of these key maturation enzymes – PolB1 – with other replisome proteins was examined. It was demonstrated that PolB1 exists in a trimeric complex in vivo with two previously unidentified factors, raising the possibility of uncharacterised activities and interactions for this crucial enzyme. Taken together, these data provide new insights into functionally important protein-protein interactions within the archaeal replisome, and facilitate a greater understanding of the DNA replication machinery in both archaea and eukaryotes. 572.8645
4	Structural investigation of the archaeal replicative machinery by electron microscopy and digital image processing Cannone, Giuseppe January 2015 (has links) Previous studies suggest a degree of homology between eukaryotic replication, transcription and translation proteins and archaeal ones. Hence, Archaea are considered a simplified model for understanding the complex molecular machinery involved in eukaryotic DNA metabolism. DNA replication in eukaryotic cells is widely studied. In recent years, DNA replication studies expanded on the archaeal DNA replication machinery. P. abyssi was the first archaeon whose genome was fully sequenced. Genome sequencing and comparative genomics have highlighted an MCM-like protein in P. abyssi. In this study, I report the biochemical and structural characterisation of PabMCM. PabMCM is explored as model for understanding more complex eukaryotic MCM proteins and unravelling the biochemical mechanism by which MCM proteins release their helicase activity. The crenarchaeon Sulfolobus solfataricus possesses a simplified toolset for DNA replication compared to Eukaryotes. In particular, S. solfataricus has a subset of the eukaryotic Okazaki fragment maturation factors, among which there are a heterotrimeric DNA sliding clamp, (the proliferating cell nuclear antigen, PCNA), the DNA polymerase B1 (PolB1), the flap endonuclease (Fen1) and the ATP-dependent DNA ligase I (LigI). PCNA functions as a scaffold with each subunit having a specific binding affinity for each of the factors involved in Okazaki fragment maturation. Here, the 3D reconstruction of PCNA in complex with the Okazaki fragment maturation proteins PolB1, LigI and Fen1 is reported. 572.8
5	Structure of eukaryotic DNA polymerase epsilon and lesion bypass capability Sabouri, Nasim January 2008 (has links) To transfer the information in the genome from mother cell to daughter cell, the DNA replication must be carried out only once and with very high fidelity prior to every cell division. In yeast there are several different DNA polymerases involved in DNA replication and/or DNA repair. The two replicative DNA polymerases, DNA polymerase delta (Pol delta) and DNA polymerase epsilon (Pol epsilon), which both include a proofreading 3´→5´exonuclease activity, can replicate and proofread the genome with a very high degree of accuracy. The aim of this thesis was to gain a better understanding of how the enigmatic DNA polymerase epsilon participates in DNA transactions. To investigate whether Pol epsilon or Pol delta is responsible for the synthesis of DNA on the lagging strand, the processing and assembly of Okazaki fragments was studied. Pol delta was found to have a unique property called “idling” which, together with the flap-endonuclease (FEN1), maintained a ligatable nick for DNA ligase I. In contrast, Pol epsilon was found to lack the ability to “idle” and interact functionally with FEN-1, indicating that Pol epsilon is not involved in processing Okazaki fragments. Together with previous genetic studies, it was concluded that Pol delta is the preferred lagging strand polymerase, leaving Pol epsilon to carry out some other function. The structure of Pol epsilon was determined by cryo-electron microscopy, to a resolution of ~20 Å. Pol epsilon is composed of a globular “head” domain consisting of the large catalytic subunit Pol2p, and a “tail” domain, consisting of the small subunits Dpb2p, Dpb3p, and Dpb4p. The two separable domains were found to be connected by a flexible hinge. Interestingly, the high intrinsic processivity of Pol epsilon depends on the interaction between the tail domain and double-stranded DNA. As a replicative DNA polymerase, Pol epsilon encounters different lesions in DNA. It was shown that Pol epsilon can perform translesion synthesis (TLS) through a model abasic site in the absence of external processivity clamps under single-hit conditions. The lesion bypass was dependent of the sequence on the template and also on a proper interaction of the “tail”domain with the primer-template. Yeast cells treated with a DNA damaging agent and devoid of all TLS polymerases showed improved survival rates in the presence of elevated levels of dNTPs. These genetic results suggested that replicative polymerases may be engaged in the bypass of some DNA lesions. In vitro, Pol epsilon was found to bypass 8-OxoG at elevated dNTP levels. Together, the in vitro and in vivo results suggest that the replicative polymerases may be engaged in bypass of less bulky DNA lesions at elevated dNTP levels. In conclusion, the low-resolution structure presented represents the first structural characterization of a eukaryotic multi-subunit DNA polymerase. The replicative DNA polymerase Pol epsilon can perform translesion synthesis due to an interaction between the tail domain and double-stranded DNA. Pol epsilon may also bypass less bulky DNA lesions when there are elevated dNTP concentrations in vivo. DNA polymerase epsilon DNA replication Okazaki fragment Translesion synthesis DNA lesion dNTP Biochemistry Biokemi
6	Defining the Role of Lysine Acetylation in Regulating the Fidelity of DNA Synthesis Ononye, Onyekachi Ebelechukwu 12 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Accurate DNA replication is vital for maintaining genomic stability. Consequently, the machinery required to drive this process is designed to ensure the meticulous maintenance of information. However, random misincorporation of errors reduce the fidelity of the DNA and lead to pre-mature aging and age-related disorders such as cancer and neurodegenerative diseases. Some of the incorporated errors are the result of the error prone DNA polymerase alpha (Pol α), which initiates synthesis on both the leading and lagging strand. Lagging strand synthesis acquires an increased number of polymerase α tracks because of the number of Okazaki fragments synthesized per round of the cell cycle (~50 million in mammalian cells). The accumulation of these errors invariably reduces the fidelity of the genome. Previous work has shown that these pol α tracks can be removed by two redundant pathways referred to as the short and long flap pathway. The long flap pathway utilizes a complex network of proteins to remove more of the misincorporated nucleotides than the short flap pathway which mediates the removal of shorter flaps. Lysine acetylation has been reported to modulate the function of the nucleases implicated in flap processing. The cleavage activity of the long flap pathway nuclease, Dna2, is stimulated by lysine acetylation while conversely lysine acetylation of the short flap pathway nuclease, FEN1, inhibits its activity. The major protein players implicated during Okazaki fragment processing (OFP) are known, however, the choice of the processing pathway and its regulation by lysine acetylation of its main players is yet unknown. This dissertation identifies three main findings: 1) Saccharomyces cerevisiae helicase, petite integration frequency (Pif1) is lysine acetylated by Esa1 and deacetylated by Rpd3 regulating its viability and biochemical properties including helicase, binding and ATPase activity ii) the single stranded DNA binding protein, human replication protein A (RPA) is modified by p300 and this modification stimulates its primary binding function and iii) lysine acetylated human RPA directs OFP towards the long flap pathway even for a subset of short flaps. DNA Replication Lysine Acetylation PTM Lagging Strand Okazaki Fragment Maturation Replication Protein A Pif1 RPA
7	Determination of DNA replication program changes between cancer and normal cells by sequencing of Okazaki fragments / Étude des modifications du programme de réplication de l'ADN par séquençage des fragment d'Okazaki Wu, Xia 29 September 2016 (has links) Jusqu'à présent, les modifications de la réplication de l'ADN entre cellules normales et cancéreuses ont été peu étudiées. Dans ce travail, nous avons utilisé le séquençage des fragments d'Okazaki, une technique récemment développée au laboratoire, pour déterminer la directionalité des fourches de réplication dans plusieurs lymphomes de Burkitt (LB), qui surexpriment l'oncoprotéine Myc à la suite de translocations chromosomiques spécifiques, ainsi que dans des lignées lymphoblastoides contrôles (LLC) et dans des léiomyosarcomes (LMS). Les profils de directionalité des fourches de réplication permettent de déduire la localisation et l'efficacité des sites d'initiation et de terminaison de la réplication le long du génome. Nous avons observé de nombreuses (~2000) différences de zones d'initiation entre les lignées Raji (LB) et GM06990 (LLC) ainsi qu'entre les lignées BL 79 et IARC385, une paire LB/LLC provenant d'un même patient. Nous avons détecté un nombre comparable de différences en comparant deux à deux les lignées étudiées. Cependant, les profils de BL79 et de Raji (deux LB) sont un peu plus proches l'un de l'autre que de la lignée contrôle GM06990. Ceci suggère l'existence de changements de la réplication récurrents dans les lignées LB. L'importance des différences observées entre les lignées IARC385 et GM06990 indique de façon surprenante une grande variabilité entre les LLC normales, provenant de différents individus. De façon intéressante, de nombreuses différences observées entre les lignées LB et LLC sont associées à des changements de l'expression des gènes ou de la liaison de l'oncoprotéine Myc. La comparaison des profils des deux LMS avec tous les profils disponibles au laboratoire montre que c'est à celui de fibroblastes normaux (IMR90) qu'ils ressemblent le plus. Ceci suggère que les cellules de tumeurs musculaires lisses auraient subi une transformation fibroblastique au cours de la tumorigénèse. Des données récentes suggèrent que les champs magnétiques peuvent perturber certains processus cellulaires comme l'assemblage du cytosquelette. Nous avons utilisé le séquençage de fragment d'Okazaki pour rechercher d'éventuels effets d'un champ magnétique sur la réplication de l'ADN chez la levure. Aucun effet du champ magnétique sur la directionalité des fourches de réplication n'a été détecté. / Changes in DNA replication profiles between cancer and normal cells have been poorly explored. In this work, sequencing of Okazaki fragments, a novel methodology developed in the laboratory, was used to determine replication fork directionality (RFD) in several Burkitt's lymphomas (BL), which overexpress the Myc oncoprotein due to specific chromosomal translocations, and control normal lymphoblastoid cell lines (LCL), and in leiomyosarcomas (LMC). RFD profiles allow to infer the location and efficiency of replication initiation and termination sites genome-wide. A larger number (~2000) of differences in replication initiation zones were observed genome-wide between Raji (BL) and GM06990 (LCL), and between BL79 and IAR385, a BL / LCL pair of cell lines established from a single patient. Comparably large numbers of changes were slightly more similar to each other than to GM06990. This suggests the occurrence of some recurrent replication changes in BL cell lines. The large number of changes observed between IARC385 and GM06990 also indicates an unexpectedly large variation between normal LCLs of different individuals. Interestingly, many changes in RFD profiles between BLs and and LCLs are associated with cell-type specific gene expression and differential binding of the Myc oncoprotein. Comparison of the two LMS profiles with all RFD profiles available in the laboratory reveals that they most resemble normal fibroblasts (IMR90). This suggests that the smooth muscle cancer cells might have undergone a fibroblastic transformation during tumorigenesis. Magnetic fields have been reported to perturb cellular processes such as cytoskeleton assembly. Sequencing of Okazaki fragments was used in a preliminary investigation of the possible effects of magnetic fields on DNA replication in yeast cells. No effect of magnetic fields on replication fork directionality were observed. Programme de réplication du génome Genome replication program Okazaki fragment sequencing Replication stress Genome instability Burkitt's lymphoma Leiomyosarcoma Magnetic field Myc 572.8
8	Structural and Biophysical Studies of Single-Stranded DNA Binding Proteins and dnaB Helicases, Proteins Involved in DNA Replication and Repair Johnson, Vinu January 2007 (has links) No description available. Biology, Microbiology Biology, Molecular Biophysics, General Chemistry, Biochemistry Chemistry, General SSB proteins Single-Stranded DNA Binding Proteins Archaeal SSB Okazaki fragment processing Structure of SSB Helicases
9	A Study of Single-stranded DNA Gaps in the Response to Replication Stress and Synthetic Lethality Cong, Ke 03 January 2022 (has links) Mutations in the hereditary breast/ovarian cancer genes BRCA1/2 were shown to be synthetic lethal with poly(ADP-ribose) polymerase inhibitors (PARPi). This toxicity is assumed to derive from PARPi-induced DNA double strand breaks (DSBs) that necessitate BRCA function in homologous recombination (HR) and/or fork protection (FP). However, PARPi accelerates replication forks. While high-speed replication could cause DSBs, the finding that PARPi leads to single-stranded DNA (ssDNA) gaps/nicks suggests replication gaps could also or alone be the cause of synthetic lethality. Here, we demonstrate that PARPi toxicity derives from replication gaps. Isogenic cells deficient in BRCA1 or the BRCA1-associated FANCJ, with common DNA repair defects in HR and FP, exhibit opposite responses to PARPi. Deficiency in FANCJ, a helicase also mutated in hereditary breast/ovarian cancer and Fanconi anemia, causes aberrant accumulation of fork remodeling factor HLTF and limits unrestrained DNA synthesis with ssDNA gaps. Thus, we predict replication gaps as a distinguishing factor and further uncouple HR, FP and fork speed from PARPi response. BRCA-deficient cells display excessive gaps that are diminished upon resistance, restored upon re-sensitization and when targeted augment synthetic lethality with PARPi. Furthermore, we define the source of gaps to defects in Okazaki fragment processing (OFP). Unchallenged BRCA1-deficient cells have elevated poly(ADP-ribose) and chromatin-associated PARP1 but aberrantly low XRCC1 indicating a defective backup OFP pathway. Remarkably, 53BP1 loss resuscitates OFP by restoring XRCC1-LIG3 that suppresses the sensitivity of BRCA1-deficient cells to drugs targeting OFP or generating gaps. Collectively, our study highlights unprotected lagging strand gaps as a determinant of synthetic lethality, providing a new paradigm and biomarker for PARPi toxicity. Single-stranded DNA gaps Replication stress FANCJ HLTF Fanconi anemia Fork protection BRCA1/2 deficiency Homologous recombination PARP inhibitor Synthetic lethality Gap suppression Okazaki fragment processing Chemo-resistance Cancer therapy Cancer Biology

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