The mechanism of DNA double-strand break (DSB) resection in human cells

Yang, Soo-Hyun

05 November 2013

Homologous recombination (HR) repair is critical for the maintenance of genomic stability, as it is involved in the precise repair of DNA double-strand breaks (DSBs) using an intact homologous template for repair. The initiation of 5' strand resection of DNA ends is a critical determinant in this process, which commits cells to HR repair and prevents repair by non-homologous end joining (NHEJ). The human single-stranded DNA (ssDNA) binding complexes, RPA and SOSS1, are involved in regulating DSB signaling and HR repair. In this study, I demonstrate a novel function of SOSS1 in HR repair, in which SOSS1 stimulates hExo1-dependent resection. Despite its poor activity in binding duplex DNA, SOSS1 facilitates hExo1 recruitment to duplex DNA ends and promotes its activity in resection independently of MRN in vitro. MRN(X) is a highly conserved complex that is involved in the early steps of HR repair by regulating DSB resection. MRN interacts with CtIP and constitutes resection machinery that can perform limiting processing on DNA ends. In this study, I also examine the biochemical activities of MRN and CtIP in DSB resection through reconstituted in vitro assays. I show that the ATP-dependent DNA unwinding activity of MRN is responsible for overcoming Ku inhibition of hExo1- and Dna2/BLM-dependent resection activity in vitro. I propose that this unwinding step displaces Ku away from the DNA ends and facilitates the recruitment of hExo1 to the DNA ends for efficient resection. In addition, I show that CtIP can promote overcoming the inhibitory effect of Ku in resection together with MRN. Further, I demonstrate that MRN nuclease activity is required for efficient processing of covalent adducts from DNA ends in vitro, suggesting that the nucleolytic removal of covalent adducts by MRN generates free ends for hExo1- and Dna2/BLM binding. Overall, this study provides mechanistic insight into the regulation of DSB resection in human cells. / text

Homologous recominbation

DSB resection

MRN

SOSS1

RPA

hExo1

Dna2

CtIP

Ku70/80

Cooperative nuclease activity of the Mre11/Rad50/Xrs2 complex and Sae2 during DNA double-strand break repair

Lengsfeld, Bettina Marie

12 March 2014

DNA double-strand breaks (DSBs) are lethal in eukaryotic cells if left unrepaired. In Saccharomyces cerevisiae the Mre11/Rad50/Xrs2 (MRX) complex is required for repair of DSBs through homologous recombination and nonhomologous end joining. Although Mre11 complexes exhibit 3'[rightwards arrow]5' exonuclease activity and endonuclease activity on DNA hairpin and single-stranded DNA overhang substrates in vitro, the role of the MRX complex in homologous recombination in vivo is not well understood. It has been shown to be specifically required for the processing of protein-conjugated DNA ends at DSBs during meiosis and hairpin-capped DSBs in mitotic cells and has been suggested that the Mre11 nuclease functions to remove damaged DNA ends. Recently, the Sae2 protein has been demonstrated to be involved in hairpin-capped DSBs and DNA end processing along with MRX in vivo. However, the Sae2 protein has no known homologs outside of fungi and no obvious motifs to suggest the function(s) of the Sae2 protein. We have purified recombinant Sae2 and MRX and report that the Sae2 protein itself is a single-stranded DNA endonuclease. The Sae2 protein stimulates the 3[rightwards arrow]5' exonuclease activity of the MRX complex. Also, the MRX complex can stimulate Sae2 nuclease activity to cleave ssDNA adjacent to DNA hairpin structures. The Sae2 protein also binds independently to double-stranded DNA and forms higher order protein-DNA complexes with MRX. These results provide biochemical evidence for functional cooperatively between MRX and Sae2 on DSBs and hairpin-capped DNA ends. / text

Double-strand breaks

Homologous recombination

Nonhumologous end joining

Exonuclease activity

Hairpin-capped DNA ends

Comparison of several protocols for the increase in homologous recombination in normal porcine fetal fibroblasts and the application to an actual locus

Zaunbrecher, Gretchen Marie

30 September 2004

Together with the advancements in animal cloning, the ability to efficiently target specific genes in somatic cells would greatly enhance several areas of research. While it has been possible for quite some time to target specific genes in the germ cells of mice, the advancements in somatic cell gene targeting has been slowed for two main reasons. First, the finite lifespan of somatic cells, due mainly to the inability of the somatic cells to regenerate or maintain their telomeres, poses a major problem given the lengthy selection process needed to identify a targeting event. The second problem is the overall inefficiency of homologous recombination. A double strand break or introduction of foreign DNA into a cell can be processed either through the homologous recombination or non-homologous end joining pathways. Of these two, non-homologous end joining is dominant in somatic cells. A two plasmid recombination system was used to study the effects of the manipulation of several non-homologous end joining and homologous recombination pathway molecules on the rates of homologous recombination in porcine fetal fibroblasts. In addition, the effect of telomerase expression, cell synchrony, and DNA nuclear delivery was examined. Results indicate a strong positive relationship between inactivation of p53, cell synchronization, and efficient DNA nuclear delivery in enhancing the rate of homologous recombination. These findings were then applied to an actual locus in the pig, the α1,3 galactosyltransferase gene. Results from these transfections are compared to published accounts of successful targeting at this locus and possibilities for the differences found are discussed.

homologous recombination

enhancer protocols

alpha 1-3 galactosyltransferase

porcine fetal fibroblasts

Investigating the Role of Rad51 in Mammalian Ectopic Homologous Recombination

Knapp, Jennifer

12 July 2013

DNA damage occurs through endogenous and exogenous sources, and can lead to stalled replication forks, genetic disorders, cancer, and cell death. Homologous recombination (HR) is a relatively fast and error-free repair pathway for damaged DNA, which can occur through a gene conversion event or through a crossing-over event with the exchange of genetic material. Homologous recombination occurs most frequently in the G2 phase of the cell cycle and utilizes the sister chromatid as the repair template. When the sister chromatid is unavailable, the homologous chromosome or a homologous sequence in an ectopic location can be used to repair the lesion; the latter of which is referred to as ectopic homologous recombination (EHR). Rad51 is a key protein involved in HR, and to test its role in EHR, variant Rad51 proteins were expressed in murine hybridoma cells. These Rad51 variants were assayed for their effects on EHR. Excess wild-type Rad51 as well as a deficiency of wild-type Rad51 decreased EHR from the background level found in these cell lines. Thus, Rad51 is necessary for EHR, but there may be an optimal amount of Rad51 required for efficient EHR. Expression of the Rad51 catalytic mutants Rad51K133A and Rad51K133R was found to have an inhibitory effect on EHR, as expected based on the loss of ATP binding and ATP hydrolysis, respectively, in these variants. Excess wild-type Rad51 was verified in this study to increase HR via a gene targeting assay. MMC treatment, but not ionizing radiation, leads to an increase in EHR in the presence of excess wild-type Rad51. Thus, endogenous levels of Rad51 are sufficient to maintain EHR, but in the presence of excess wild-type Rad51, the level of EHR can increase in response to certain DNA damaging agents and in response to gene targeting.

Ectopic homologous recombination

Murine hybridoma cells

Rad51

DNA damage

Gene Targeting

STRUCTURAL INSTABILITY OF HUMAN RIBOSOMAL RNA GENE CLUSTERS

Stults, Dawn Michelle

01 January 2010

The human ribosomal RNA genes are critically important for cell metabolism and viability. They code for the catalytic RNAs which, encased in a housing of more than 80 ribosomal proteins, link together amino acids by peptide bonds to generate all cellular proteins. Because the RNAs are not repeatedly translated, as is the case with messenger RNAs, multiple copies are required. The genes which code for the human ribosomal RNAs (rRNAs) are arranged as clusters of tandemly repeated sequences. Three of four catalytic RNAs are spliced from a single transcript. The genes are located on the short arms of the five acrocentric chromosomes (13, 14, 15, 21, and 22). The genes for the fourth rRNA are on chromosome 1q42, also arranged as a cluster of tandem repeats. The repeats are extremely similar in sequence, which makes them ideal for misalignment, non‐allelic homologous recombination (NAHR), and genomic destabilization during meiosis , replication, and damage repair. In this dissertation, I have used pulse‐field gel electrophoresis and in‐blot Southern hybridization to explore the physical structure of the human rRNA genes and determine their stability and heritability in normal, healthy individuals. I have also compared their structure in solid tumors compared to normal, healthy tissue from the same patient to determine whether dysregulated homologous recombination is an important means of genomic destabilization in cancer progression. Finally, I used the NCI‐60 panel of human cancer cell lines to compare the results from the pulsed‐field analysis, now called the gene cluster instability (GCI) assay, to two other indicators of homologous‐recombination-mediated genomic instability: sister chromatid exchange, and 5‐hydroxymethyl‐2’deoxyuridine sensitivity.

genomic instability

cancer

DNA repair

ribosomal RNA

Medical Toxicology

LOSS OF BLOOM SYNDROME PROTEIN CAUSES DESTABILIZATION OF GENOMIC ARCHITECTURE AND IS COMPLEMENTED BY ECTOPIC EXPRESSION OF Escherichia coli RecG IN HUMAN CELLS

Killen, Michael Wayne

01 January 2011

Genomic instability driven by non-allelic homologous recombination (NAHR) provides a realistic mechanism that could account for the numerous chromosomal abnormalities that are hallmarks of cancer. We recently demonstrated that this type of instability could be assayed by analyzing the copy number variation of the human ribosomal RNA gene clusters (rDNA). Further, we found that gene cluster instability (GCI) was present in greater than 50% of the human cancer samples that were tested. Here, data is presented that confirms this phenomenon in the human GAGE gene cluster of those cancer patients. This adds credence to the hypothesis that NAHR could be a driving force for carcinogenesis. This data is followed by experimental results that demonstrate the same gene cluster instability in cultured cells that are deficient for the human BLM protein. Bloom’s Syndrome (BS) results from a genetic mutation that results in the abolition of BLM protein, one of human RecQ helicase. Studies of Bloom’s Syndrome have reported a 10-fold increase in sister chromatid exchanges during mitosis which has primarily been attributed to dysregulated homologous recombination. BS also has a strong predisposition to a broad spectrum of malignancies. Biochemical studies have determined that the BLM protein works in conjunction with TOPOIIIα and RMI1/RMI2 to function as a Holliday Junction dissolvase that suppress inadvertent crossover formation in mitotic cells. Because of the similarities in their biochemical activities it was suggested that another DNA helicase found in E. coli, the RecG DNA translocase, is the functional analog of BLM. RecG shares no sequence homology with BLM but it can complement both the sister chromatid exchange elevation and the gene- cluster instability phenotype caused by BLM deficiency. This indicates that the physiological function of BLM that is responsible for these phenotypes rests somewhere in the shared biochemical activities of these two proteins. These data taken together give new insights into the physiological mechanism of BLM protein and the use of Bloom’s Syndrome as a model for carcinogenesis.

Bloom’s Syndrome

BLM

homologous recombination

genomic instability

cancer

Biochemistry

Cell Biology

Genetics

Mechanisms of chromosomal instability induced by unstable DNA repeats in yeast S.cerevisiae

Zhang, Yu

27 August 2014

DNA repetitive sequences capable of adopting non-B DNA structures are a potent source of instability in eukaryotic genomes. They are strong inducers of chromosomal fragility and genome rearrangements that cause various hereditary diseases and cancers. In addition, a subset of repeats also has an ability to expand, which leads to more than 20 human genetic diseases that are collectively known as repeat expansion diseases. However, the mechanisms underlying the potential of these structure-prone motifs to break and expand are largely unknown. In this study, a systematic genome-wide screen was employed in yeast Saccharomyces cerevisiae to investigate the contributing factors of the instability of two representative non-B DNA-forming repeats: the triplex-adopting GAA/TTC tracts and the inverted repeats that can form hairpin and cruciform structures. The GAA/TTC screen revealed that DNA replication and transcription initiation are the two major pathways governing the GAA/TTC stability in yeast, as corresponding mutants strongly induce both fragility and large-scale expansions of the repeats. The inverted repeats screen and follow-up experiments revealed that both replication-dependent and -independent pathways are involved in maintaining the stability of palindromic sequences. We propose that similar mechanisms could operate in the human cells to mediate the deleterious metabolism of GAA and inverted repeats.

GAA/TTC repeats

Palindromic sequence

Fragility

Expansion

Instability

Replication

Transcription

Homologous recombination

Time-dependent behavior of pretensioned stainless steel bars used for structural rehabilitation and retrofitting

Shah, Falak Dipak

12 January 2015

The objective of this study is to characterize the long-term behavior of an austenitic-ferritic stainless steel-based pretensioned system for strengthening reinforced concrete bridge pier caps in shear. Stress relaxation experiments were conducted on UNS S32101 stainless steel bars subjected to various initial stresses and temperatures within the low homologous temperature (LHT) regime. Data from these experiments were used to develop a viscoplastic constitutive model to describe the long-term time- and temperature-dependent behavior of the stainless steel bars. This mechanics-based approach is integrated with an analytical method based on strut-and-tie analysis to compute the shear strength of reinforced concrete pier caps strengthened with this external pretensioned system.

Duplex stainless steel

Stainless steel

Viscoelasticity

Stress relaxation

Structural strengthening

Structure and thermoelectric transport properties of isoelectronically substituted (ZnO)5In2O3

Masuda, Yoshitake, Ohta, Mitsuru, Seo, Won-Seon, Pitschke, Wolfram, Koumoto, Kunihito, 増田, 佳丈, 河本, 邦仁

15 February 2000

No description available.

crystal structure

Rietveld refinement

thermoelectric properties

zinc oxide

indium oxide

homologous series

Development of intimal hyperplasia in transplant arteriosclerosis /

Religa, Piotr,

January 2003

Diss. (sammanfattning) Stockholm : Karol. inst., 2003. / Härtill 4 uppsatser.