Study of minichromosome-maintenance-deficient 4 (MCM4) gene in breast cancer

Ting, Kam-po., 丁金寶.

January 2009

published_or_final_version / Pathology / Master / Master of Philosophy

Estrogen - Receptors

DNA replication.

Breast - Cancer - Genetic aspects.

The Effects of Mitochondrial DNA Mutations on Cell Growth

Tsao, Chihyi

January 2005

Mitochondrial DNA encodes thirteen protein subunits in the oxidative phosphorylation system (OXPHOS) that is responsible for cellular energy production. Mitochondrial disorders have been identified to be associated with mtDNA mutations. However, the molecular mechanisms of specific mtDNA mutations are still being explored in order to establish causative links. This study tries to elucidate the mutational effects of mtDNA on OXPHOS complex activities and cell growths. Using mouse 3T3 fibroblasts as a cell model, single-cell clones with different growth rates were isolated. The entire mtDNA genome was sequenced for mutations. The enzymatic activities of OXPHOS complex I to V were analysed. Three growth patterns represented by five clones were identified. Three clones (clone #2, #3, and #6) had the shortest doubling times (11.5 - 14.9 hours). Clone #1 had a medium growth rate (19.2 hous); and clone #5 had a significantly slow growth rate (22 hours). MtDNA sequencing results revealed that clone #5 had several heteroplasmic mutations (one in 16S rRNA, two in tRNAser (UCN), three in tRNAasp, one in tRNAlys, one in COI, five in COII, and one in ATPase8) while the other four clones showed sequence homology. Enzymatic analyses showed that on average clone #5 had significantly low complex III, IV, and V activities (p < 0.05). Changes in biochemical properties and protein structure were analyzed to deduct possible mechanisms for reduced respiration. In conclusion, the slow growth rate is associated with reduced OXPHOS enzyme functions. It is most likely that the combination of COI and COII mutations resulted in the reduction of complex IV function. It is still unclear whether the ATPase8 mutation (T7869A) in the non-conserved region alone can have such a pronounced phenotypic effect. A reduction in complex III also cannot be explained since there were no mutations in the only mtDNA-encoded complex III gene, but it is possible that there are mutations in the nDNA-encoded complex III genes. Mutations in tRNA and rRNA genes may also be responsible for reduced protein syntheses and consequently reduced OXPHOS activities. It is unclear why complex I activity was not affected. Although the mutational effect of individual mtDNA mutation observed cannot be clearly identified, this study establishes a correlation between mtDNA mutation and cell energy production and growth.

mitochondrial

genomes

DNA replication

cell culture

clone

mutations

Role of S. cerevisiae Yta7p in DNA replication

Curley, Rebecca

January 2010

In S. cerevisiae initiation of replication occurs from discrete sites in the genome, known as origins and these display a characteristic temporal profile of activation during S phase of the cell cycle. The genomic context of origins has been demonstrated to be important to determine the time of firing, more specifically histone acetylation levels surrounding origins can influence their activation time. How increased acetylation is translated into earlier firing of specific origins is currently unknown. Bromodomains are known to bind acetylated histones in vivo. The bromodomain-containing Yta7p has been identified in a complex with various remodelers of chromatin and subunits of DNA polymerase ǫ. It is also a target of cell cycle and checkpoint kinases. Therefore, Yta7p makes an excellent candidate to bind acetylated histones surrounding replication origins and affect an alteration in the chromatin structure that could influence time of firing. Deletion of the histone deacetylase RPD3 results in a rapid S phase phenotype due to increased histone acetylation at “late-firing” origins. Increased acetylation at “late” origins leads to an advance in the time of firing of those specific origins. The aim of this study was to investigate the hypothesis that the bromodomain-containing protein Yta7p binds to histones with increased acetylation near to replication origins and subsequently influences origin firing. Hence, deletion of YTA7 would abolish the rapid S phase of a ∆rpd3 strain. Indeed the S phase of the ∆rpd3∆yta7 strain was reverted to WT duration. A role for Yta7p in DNA replication is also inferred by two additional lines of evidence presented in this thesis. Synthetic growth defects are evident when YTA7 and RPD3 deletion is combined with mutation of a third replication protein. In addition, ∆rpd3∆yta7 mutants are sensitive to HU, which is a phenotype shared by many strains with deletions in genes that encode proteins involved in DNA replication. Evidence to support a direct role of Yta7p in DNA replication events is provided by identification of an S phase specific binding of Yta7p to replication origins. Moreover, levels of Yta7p bound to early-firing origins are increased compared with their later-firing counterparts. Levels of Yta7p that are bound to “late-firing” origins are only increased in conditions of RPD3 deletion, where the resulting increase in histone acetylation at the “late-firing” origins is associated with advanced time of firing. Time of Yta7p binding at these “late” origins is also advanced concomitantly. This data supports the hypothesis that Yta7p provides a functional link between histone acetylation and time of origin activation. In searching for a specific replication linked function of Yta7p it was observed that recruitment of the FACT subunit Spt16p to replication origins was increased in conditions of YTA7 deletion. A second function for Yta7p in the S phase checkpoint was also demonstrated and the two roles of Yta7p, in DNA replication and S phase checkpoint, were separated depending upon their requirement for the bromodomain. The data produced in this thesis adds to our knowledge of DNA replication events and highlights the importance of histone modifications and chromatin remodeling to the replication field. This thesis describes the direct involvement of a protein, which was previously unassociated, with DNA replication and S phase checkpoint function and provides good ground work for future investigation.

572.8

Alternativas da replicação do DNA: vias de controle e dinâmica das forquilhas em trypanosomas. / DNA replication alternatives: control pathways and fork dynamic in trypanosomas.

Calderano, Simone Guedes

03 December 2013

A replicação do DNA tem início nas origens de replicação que são licenciadas na transição das fases M/G1, pelo complexo de pré-replicação (CPR), e ativadas apenas na fase S. Existem diversas origens de replicação no genoma, mas apenas parte destas origens é disparada em diferentes momentos de S, havendo assim origens early (disparadas no início de S) e late (disparadas mais tardiamente). Em trypanosomas as origens de replicação são reconhecidas por um CPR formado por Orc1/Cdc6 e pelo complexo MCM2-7. Em T. cruzi observamos que existem dois mecanismos diferentes para controlar a replicação do DNA. Durante o ciclo celular da forma epimastigota, as proteínas do CPR são sempre expressas e ligadas ao DNA, mas durante o ciclo de vida Orc1/Cdc6 se liga ao DNA apenas nas formas que replicam, e Mcm7 não é expressa nas que não replicam. Também foi analisado o perfil das forquilhas de replicação em T. brucei utilizando a técnica de SMARD onde vimos que a velocidade da forquilha é semelhante a dos demais eucariontes, além de encontrarmos a primeira origem de replicação late. / The DNA replication starts at the origins of replication, which are licensed at M/G1 transition, by the pre replication complex (PRC), and are activated just at S phase. There are many origins of replication along genome, but some of them are fired at different moments of S phase. So there are early and late origins fired at the beginning or later in S phase, respectively. The PRC of trypanosomes is composed of Orc1/Cdc6 and Mcm2-7. We could observe that in T. cruzi there are two distinct ways to control DNA replication. Whereas in epimastigote cell cycle the PRC are expressed and bound to DNA in all phases, during T. cruzi life cycle Orc1/Cdc6 is bound to DNA only in replicative forms and Mcm7 is absent in the non-replicative forms. We also analyzed the fork profile in T. brucei through SMARD technique. We found that the speed of replication fork is similar from other eukaryotes and that different replication origins are fired every cell cycle. Finally, we found a new origin of replication that is the first late origin described in this organism.

Trypanosoma cruzi

Trypanosoma cruzi

Trypanosoma

Trypanosoma

DNA replication

Replicação do DNA

Watching the Replisome: Single-molecule Studies of Eukaryotic DNA Replication

Duzdevich, Daniel

January 2017

The molecules of life are small to us—billionths of our size. They move fast too, and in the cell they crowd together impossibly. Bringing that strange world into ours is the trick of molecular biology. One approach is to harness many copies of a molecule and iterate a reaction many times to glimpse what happens at that small, foreign scale. This is a powerful way to do things and has provided major insights. But ultimately, the fundamental unit of molecular biology is the individual molecule, the individual interaction, the individual reaction. Single-molecule bioscience is the study of these phenomena. Eukaryotic DNA replication is particularly interesting from the single-molecule perspective because the biological molecules responsible for executing the replication pathway interact so very intricately. This work is based on replication in budding yeast—a model eukaryote. The budding yeast genome harbors several hundred sequence-defined sites of replication initiation called origins. Origins are bound by the Origin Recognition Complex (ORC), which recruits the ring-shaped Mcm2-7 complex during the G1 phase of the cell cycle. A second Mcm2-7 is loaded adjacent to the first in a head-to-head orientation; this Mcm2-7 double hexamer encircles DNA and is generally termed the Pre-Replicative Complex, or Pre-RC. Mcm2-7 loading is strictly dependent on a cofactor, Cdc6, which is expressed in late G1. Much less is known about the details of downstream steps, but a large number of factors assemble to form active replisomes. Origin-specific budding yeast replication has recently been reconstituted in vitro, with cell cycle dependence mimicked by the serial addition of purified Pre-RC components and activating kinases. This work introduces the translation of the bulk biochemical replication assay into a single-molecule assay and describes the consequent insights into the dynamics of eukaryotic replication initiation. I have developed an optical microscopy-based assay to directly visualize DNA replication initiation in real time at the single-molecule level: from origin definition, through origin licensing, to replisome formation and progression. I show that ORC has an intrinsic capacity to locate and stably bind origin sequences within large tracts of non-origin DNA, and that ordered Pre-RC assembly is driven by Cdc6. I further show that the dynamics of the ORC-Cdc6 interaction dictate the specificity of Mcm2-7 loading, and that Mcm2-7 double hexamers form preferentially at a native origin sequence. This work uncovers key variables that control Pre-RC assembly, and how directed assembly ensures that the Pre-RC forms properly and selectively at origins. I then characterize replisome initiation and progression dynamics. I show that replication initiation is highly precise and limited to Mcm2-7 double hexamers. Sister replisomes fire bidirectionally and simultaneously, suggesting that previously unidentified quality control mechanisms ensure that a complete pair of replisomes is properly assembled prior to firing. I also find that single Mcm2-7 hexamers are sufficient to support processive replisome progression. Moreover, this work reveals that replisome progression is insensitive to DNA sequence composition at spatial and temporal scales relevant to the replication of an entire genome, indicating that separation of the DNA strands by the replicative helicase is not rate-limiting to replisome function. I subsequently applied this replication assay to the study replisome-replisome collisions, a fundamental step in the resolution of convergent replication forks. I find that, surprisingly, active replisomes absolutely lack an intrinsic capacity to displace inactive replisomes. This result eliminates the simplest hypothesized mechanism for how the cell resolves the presence of un-fired replisomes and has prompted and guided the development of alternate testable hypotheses. Taken together, these observations probe the molecular basis of eukaryotic inheritance in unprecedented detail and offer a platform for future work on the many dynamic aspects of replisome behavior.

DNA replication

Molecular biology

Cytology

Eukaryotic cells--Genetics

Biology

Biophysics

Single-molecule observations of hRPA, RAD51, and RAD52 on single-stranded DNA

Ma, Chu Jian

January 2017

Deoxyribonucleic acid (DNA), like the hard drive in a computer, stores all the essential information for cell function and survival in nearly every single cell in our body. Four different bases are the building blocks of DNA that encode all the messages. As each cell divides, it must pass down its entire genomic DNA to both of its daughter cells. Given the vast amount of data that exists, many errors occur naturally every day and threaten the integrity of this biological hard drive. Normal cells are equipped with many repair tools to quickly and effectively respond to the lesions. When some of these errors disrupt the tightly regulated cell division, cells could undergo changes like an increase in the rate of division that eventually lead to cancer. One type of DNA damage that has a high propensity to cause genetic instability is the double-stranded break (DSB). Therefore, mechanisms that repair DSB are an important area of study in the fight against cancer and cancer causing syndromes. One of these repair pathways is homologous recombination (HR), which uses homologous sequences from either a sister chromatid or a homologue to fill in the information lost during a DSB. This homology pairing reaction requires a class of ATP-dependent proteins known as recombinases, with RAD51 being the one for humans. During HR, the early stages before pairing involve resection of the newly generated DSB ends to generate single-stranded DNA (ssDNA) overhangs, which are protected from degradation by replication protein A (RPA). RAD51 needs to displace the RPA from ssDNA and form a filament (the presynaptic complex) in order to initiate homology search. This process can be sped up by recombination mediators, which act to help RAD51 overcome the strong affinity of RPA for ssDNA that inhibits RAD51 binding and filament formation. Although Rad52 is the most important mediator in budding yeast, human RAD52 does not appear to have mediator function despite a high level of structural conservation. However, human RAD52 mediates ssDNA annealing and its deficiency is synthetic lethal with several important recombination proteins. Here, I use the single-molecule imaging technique of DNA curtains to visualize in real-time the competition and cooperativity between RPA, RAD52, and RAD51 on ssDNA through fluorescent labeling of RPA and RAD52. Using ssDNA curtains, I examine the conservation of facilitated dissociation from budding yeast to humans and show it does not require species-specific contacts. I also monitor the interactions of RAD52 with the RPA-ssDNA and find another point of conservation in the ability of RAD52 to upregulate the stability of RPA on ssDNA concerning facilitated dissociation. These RAD52-RPA-ssDNA complexes are long-lived; however, they are effectively displaced by RAD51 during filament assembly and do not re-bind appreciably to the RAD51 filament. Although RAD51 can still assemble on RAD52-RPA-ssDNA, I observe a significant inhibition on its nucleation (the first step in filament formation), but not elongation, by the presence of free RPA in solution. As DNA curtains allow efficient exchange of buffers in the micro-fluidic chambers while keeping ssDNA molecules tethered, I am able to follow individual DNA molecules overtime as they undergo different binding and filament assembly and disassembly reactions.

Biochemistry

Biophysics

DNA replication

Genetic recombination

Molecular biology

Completion of DNA Replication in <i>Escherichia coli</i>

Wendel, Brian Michael

05 June 2018

To maintain genomic integrity, all cells must accurately duplicate their genetic material in order to provide intact and complete copies to each daughter cell following cell division. Successful inheritance of chromosomal information without changing even a single nucleotide requires accurate and robust DNA replication. This requires that cells tightly control replication initiation from the origin(s), processive elongation of the replisome, and the completion of DNA replication by resolving convergent replication forks ensuring that each sequence is duplicated without alteration. Unlike initiation and elongation, the process by which replication forks converge and are resolved into two discrete, inheritable DNA molecules is not well understood. This process must be remarkably efficient, occurring thousands of times per cell division in human cells, and is likely to be a fundamental step in regulating genome stability in all cells. In this dissertation I address how DNA replication completes in the model system Escherichia coli. To achieve this, I examined candidate mutants for impairments in the completion of DNA replication. By evaluating growth, viability, chromosomal copy number, and plasmid stability I identified a requirement for the proteins RecBCD, ExoI, and SbcCD in the completion reaction. SbcCD and ExoI act before RecBCD in the completion reaction and process the DNA intermediates arising as replication forks converge. These enzymes act in the completion reaction without recombination or RecA, but in the absence of the normal process recombination is required to complete DNA replication via an aberrant pathway that results in genomic instability.

DNA replication -- Research

Chromosome replication

Mutation (Biology)

Biology

Genetics

Interstitial Telomere Sequences Disrupt Break Induced Replication

Stivison, Elizabeth Anne

January 2019

Break Induced Replication (BIR), a mechanism by which cells heal one-ended double-strand breaks, involves the invasion of a broken strand of DNA into a homologous template, and the copying of tens to hundreds of kilobases from the site of invasion to the telomere using a migrating D-loop. Here we show that if BIR encounters an interstitial telomere sequence (ITS) placed in its path, BIR terminates at the ITS 12% of the time, with the formation of a new telomere at this location. We find that the ITS can be converted to a functional telomere by either direct addition of telomeric repeats by telomerase, or by homology-directed repair using natural telomeres. This termination and creation of a new telomere is promoted by Mph1 helicase, which is known to disassemble D-loops. We also show that other sequences that have the potential to form new telomeres, but lack the unique features of a perfect telomere sequence, do not terminate BIR at a significant frequency in wild-type cells. However, these sequences can cause chromosome truncations if BIR is made less processive by loss of Pol32 or Pif1. These findings together indicate that features of the ITS itself, such as secondary structures and telomeric protein binding, pose a challenge to BIR and increase the vulnerability of the D-loop to dissociation by Mph1, promoting telomere formation at the site.

Genetics

Molecular biology

Telomere

DNA damage

DNA replication

Characterization of the Cellular and Organellar Dynamics that Occur with a Partial Depletion of Mitochondrial DNA when Arabidopsis Organellar DNA Polymerase IB is Mutated

Cupp, John D.

07 August 2012

Plant mitochondrial genomes are large and complex, and the mechanisms for maintaining mitochondrial DNA (mtDNA) remain unclear. Arabidopsis thaliana has two DNA polymerase genes, polIA and polIB, that have been shown to be dual localized to mitochondria and chloroplasts but are unequally expressed within primary plant tissues involved in cell division or cell expansion. PolIB expression is observed at higher levels in both shoot and root apexes, suggesting a possible role in organelle DNA replication in rapidly dividing or expanding cells. It is proposed that both polIA and polIB are required for mtDNA replication under wild type conditions. An Arabidopsis T-DNA polIB mutant has a 30% reduction in mtDNA levels but also a 70% induction in polIA gene expression. The polIB mutant shows an increase relative to wild type plants in the number of mitochondria that are significantly smaller in relative size, observed within hypocotyl epidermis cells that have a reduced rate of cell expansion. These mutants exhibit a significant increase in gene expression for components of mitorespiration and photosynthesis, and there is evidence for an increase in both light to dark (transitional) and light respiration levels. There is not a significant difference in dark adjusted total respiration between mutant and wild type plants. Chloroplast numbers are not significantly different in isolated mesophyll protoplasts, but mesophyll cells from the mutant are significantly smaller than wild type. PolIB mutants exhibit a three-day delay in chloroplast development but after 7dpi (days post-imbibition) there is no difference in relative plastid DNA levels between the mutant and wild type. Overall, the polIB mutant exhibits an adjustment in cell homeostasis, which enables the maintenance of functional mitochondria but at the cost of normal cell expansion rates.

polymerase gamma

PolIA

PolIB

TWINKLE

mitochondria

DNA replication

Microbiology

Molecular studies of homologous chromosome pairing in Triticum aestivum

Thomas, Stephen W. (Stephen William)

January 1997

Errata pasted on front fly-leaf. Bibliography: leaves 139-173. This thesis identifies DNA structures and genes involved in the process of homologous chromosome pairing in allohexaploid bread wheat (Triticum aestivum). In addition to studying late replicating DNA, a speculative model on the action of the pairing genes in allohexaploid wheat and the putative function of the AWWM5 gene is discussed.

Wheat Molecular genetics

Plant cytogenetics

DNA replication

Plant chromosomes Analysis