Cohesin proteins SMC1 and SMC3 : roles in aneuploidy and in meiotic chromosome dynamics /

James, Rosalina Dee.

January 2002

Thesis (Ph. D.)--University of Washington, 2002. / Vita. Includes bibliographical references (leaves 89-99).

The segregation of native and foreign extra-chromosomal genetic elements in Saccharomyces cerevisiae : stable propagation by hitchhiking on chromosomes

Liu, Yen-Ting, 1980-

07 November 2013

The 2 micron plasmid of the budding yeast Saccharomyces cerevisiae resides in the nucleus as an extra-chromosomal element with a steady state copy number around 40-60 per cell. As a benign but selfish DNA element, the plasmid utilizes a self-coded partitioning system and an amplification system to exhibit nearly chromosome-like stability in its host. Plasmid behavior under conditions that missegregate chromosomes suggest that the partitioning system couples plasmid segregation to chromosome segregation. However, the mechanism of this coupling has not been elucidated. A plausible model, consistent with current evidence, is the hitchhiking model, in which plasmid-chromosome tethering provides the basis for faithful plasmid partitioning. Testing this hypothesis unequivocally has been difficult, primarily because of the technical limitations posed by the small size of the budding yeast nucleus and poor resolution of chromosomes. As a result, cell biological assays based on fluorescence microscopy have had only modest success in addressing this problem. In the present study, I devised an experimental verification of the hitchhiking model using a single copy derivative of the 2 micron plasmid as a reporter. The rationale was to establish various conditions that force sister chromatids to co-segregate during mitosis in a bias-free manner or with a bias towards the daughter. The segregation patterns of plasmid sisters were followed under these conditions. The sum of the results from this analysis is accommodated by the hitchhiking model, with sister plasmids associating with sister chromatids in a one-to-one fashion. Episomes of mammalian viruses belonging to the gamma-herpes and papilloma families utilize a hitchhiking mechanism to persist in cells during the latent phase of their infection. Two of the viral partitioning systems have been reconstituted in S. cerevisiae. We wished to exploit these systems to characterize the efficiency of non-native chromosome tethering systems in promoting equal segregation of viral plasmids in S. cerevisiae. We find that the 2 micron plasmid partitioning system is considerably superior to the viral systems. This could be due to the higher efficiency of plasmid-chromosome association and/or due to the ability of plasmid sisters to tether to sister chromatids. / text

2 micron plasmid

Viral episome

Plasmid-chromosome tethering

Bone fracture healing in laminopathy-based premature aging

Li, Jiang, 李江.

January 2010

published_or_final_version / Biochemistry / Doctoral / Doctor of Philosophy

Mutation (Biology)

Fractures.

Bone regeneration.

Cells - Aging.

Chromosome abnormalities.

Epigenetic regulation in laminopathy-based premature aging

Zhang, Le, 张乐

January 2011

published_or_final_version / Biochemistry / Doctoral / Doctor of Philosophy

Epigenesis.

Cells - Aging.

Chromosome abnormalities.

Aging - Genetic aspects.

Genetic Characterization and Analysis of Cis and Trans-elements That Facilitate Genome Stability in Saccharomyces cerevisiae

Jones, Hope

January 2010

Chromosomal fragile sites are specific loci associated with a high frequency of breakage and recombination. A cell's ability to repair and/or replicate through a lesion is prerequisite to the maintenance of genomic stability. An improved understanding of fragile site biology and its contribution to replication defects and genomic instability is critical for prevention, intervention, and diagnosis of genetic diseases such as cancer. This work seeks to identify and characterize both trans and cis fragile sites associated elements involved in instability onset and progression. An array of Saccharomyces cerevisiae isogenic DNA repair deficient mutants were utilized to identify genes contributing to the stability or instability of a natural fragile site ~ 403 kb from the left telomere on chromosome VII. Findings suggest that the RAD52 epistasis group, the MRX complex, non-homologous end-joining (NHEJ) pathways, MUS81 and SGS1 helicases, translesion polymerases, and a majority of the post replication repair (PRR) proteins are all required for faithful replication of the 403 fragile site and likely other fragile sites as well. In contrast I found that MMS2, previously thought to be specific to the PRR pathway, is required to prevent the fusion of repetitive elements within the 403 site. mgs1 (homolog of the human Werner helicase interacting protein, WHIP) and pol3-13 (a subunit of the DNA polymerase delta) mutants also exhibited reduced instability in checkpoint deficient cells. These findings suggest previously uncharacterized function of Mgs1, Pol3 and Mms2 in regulation of genome regions at risk of replication damage. We further find the presence of inverted repeats (IR) are sufficient to induce instability. Two IR's proximal to the 403 site consistently fuse to generate acentric and dicentric chromosomes involving the 403 fragile site and a newly identified site on chromosome VII as well. The frequency of fusion events is aggravated by chromatin traffic stressors such as tRNA transcription induced fork stalling and replisome termination regions.

Chromosome instability

Dicentric

DNA replication

Inverted repeats

Transcription

Identifizierung potentieller Onkogene und therapeutischer Zielgene auf Chromosom 13q beim Kolonkarzinom / Identification of candidate oncogenes and potential therapeutical targets in colorectal cancer

Emons, Georg

05 February 2013

Kolorektale Karzinome sind durch ein spezifisches Muster chromosomaler Aberrationen charakterisiert, die im Verlauf der Tumorprogression akkumulieren. Obwohl die meisten Tumoren Sequenzgewinne oder Amplifikationen von Chromosom 13q aufweisen, sind die Zielgene dieser Aberration nach wie vor unbekannt. Um potentielle Onkogene bzw. therapeutische Zielgene auf Chromosom 13q zu identifizieren, wurde eine hochauflösende Analyse dieser Region durchgeführt. Dazu wurden 25 primäre Kolonkarzinome (UICC-II/III) und 15 kolorektale Zelllinien mittels Array-CGH untersucht. Zusätzlich wurden die Genexpressionsprofile dieser Tumoren und Zelllinien mittels Whole-Genome-Mikroarrays bestimmt. 67 Gene wiesen sowohl eine vermehrte Kopie-Anzahl als auch ein erhöhtes Expressionsniveau auf. Die Expressionsmuster dieser Gene wurden dann in 25 Kolonkarzinom-Zelllinien mittels Real-Time-PCR validiert, wobei 44 der 67 Gene eine deutliche Überexpression auch in den Zelllinien zeigten. Das Ausschalten von 13 dieser 44 Gene in der Kolonkarzinom-Zelllinie SW480 führte zu einer Reduktion der Zellviabilität von 20-60%. Diese 13 Gene könnten somit potentielle Onkogene oder mögliche therapeutische Zielgene darstellen. In Folgeexperimenten versuchen wir daher, die der Viabilitätsreduktion zugrundeliegenden Signalwege zu entschlüsseln.

610

MED 441

Colorectal cancer

Chromosome 13q

Oncogenes

RNAi

Molecular Genetic Study of Autism and Intellectual Disability Genes on the X-chromosome

Noor, Abdul

30 August 2012

Autism is a neurodevelopmental disorder with an estimated prevalence of 1 in 150 children which makes it more common than childhood cancer and juvenile diabetes. It is estimated that there are more than 100,000 individuals affected by autism in Canada and tens of millions worldwide. It is well established that genetic factors play important role in the pathophysiology of autism; still, our current understanding of these genetic factors is limited and cause of autism remains an important question. During the past decade, after completion of human genome, several new high throughput genome scan technologies have been developed such as microarrays. In the present study, we undertook the challenge of identifying X-chromosomal genes involved in autism by performing genome-wide copy number variation analysis of more than 400 probands with autism using Affymetrix 500K single nucleotide polymorphism (SNP) microarrays. We identified copy number variants implicating several genes on the chromosome X such as PTCHD1, IL1RAPL1, IL1RAPL2 and TSPAN7 as autism candidate genes. We also demonstrated that autism and intellectual disability may share some of these genes as etiologic factors. We performed a comprehensive analysis of PTCHD1 locus and showed that mutations at this locus are associated with autism in ~1 % of the cases. This study also demonstrated that PTCHD1 mutations can cause intellectually disability with or without autism, and that the PTCHD1 protein may act as a receptor in Hedgehog signaling pathway. We have also carried out a detailed analysis of TSPAN7 and IL1RAPL1 to explore the contributions of these genes in autism. We identified one family with intronic deletion of IL1RAPL1 and another case with a missense mutation in this gene, thus implicating this known intellectual disability gene in autism. Our findings highlight the importance of the X chromosome in the etiology of autism, and demonstrate the power of copy number variation analysis coupled with other technologies in identification of disease genes, in particular for complex genetic disorders such as autism.

Autism, Genomics, X chromosome

Molecular Genetic Study of Autism and Intellectual Disability Genes on the X-chromosome

Noor, Abdul

30 August 2012

Autism is a neurodevelopmental disorder with an estimated prevalence of 1 in 150 children which makes it more common than childhood cancer and juvenile diabetes. It is estimated that there are more than 100,000 individuals affected by autism in Canada and tens of millions worldwide. It is well established that genetic factors play important role in the pathophysiology of autism; still, our current understanding of these genetic factors is limited and cause of autism remains an important question. During the past decade, after completion of human genome, several new high throughput genome scan technologies have been developed such as microarrays. In the present study, we undertook the challenge of identifying X-chromosomal genes involved in autism by performing genome-wide copy number variation analysis of more than 400 probands with autism using Affymetrix 500K single nucleotide polymorphism (SNP) microarrays. We identified copy number variants implicating several genes on the chromosome X such as PTCHD1, IL1RAPL1, IL1RAPL2 and TSPAN7 as autism candidate genes. We also demonstrated that autism and intellectual disability may share some of these genes as etiologic factors. We performed a comprehensive analysis of PTCHD1 locus and showed that mutations at this locus are associated with autism in ~1 % of the cases. This study also demonstrated that PTCHD1 mutations can cause intellectually disability with or without autism, and that the PTCHD1 protein may act as a receptor in Hedgehog signaling pathway. We have also carried out a detailed analysis of TSPAN7 and IL1RAPL1 to explore the contributions of these genes in autism. We identified one family with intronic deletion of IL1RAPL1 and another case with a missense mutation in this gene, thus implicating this known intellectual disability gene in autism. Our findings highlight the importance of the X chromosome in the etiology of autism, and demonstrate the power of copy number variation analysis coupled with other technologies in identification of disease genes, in particular for complex genetic disorders such as autism.

Autism, Genomics, X chromosome

Investigation of Post-Translational Modification and Function of the Yeast Plasmid Partitioning Proteins Rep1 and Rep2

Pinder, Jordan Benjamin

04 October 2011

The 2-micron circle of Saccharomyces cerevisiae is one of a small number of similar DNA plasmids found only in budding yeast. To understand how this cryptic parasite persists, despite conferring no advantage to the host, I investigated the plasmid-encoded Rep1 and Rep2 proteins. Interaction of Rep1 and Rep2 with each other and with the plasmid STB locus is required for equal partitioning of plasmid copies at mitosis. The Rep proteins also repress expression of Flp, the recombinase that mediates plasmid copy-number amplification. In this study, absence of Rep1 and Rep2, or over-expression of the plasmid-encoded Raf antirepressor, increased expression of a longer, novel FLP transcript. Translation of this mRNA may explain elevated Flp activity at low plasmid copy number. Raf competed for Rep2 selfassociation and interaction with Rep1, suggesting the mechanism of Raf anti-repression. Deletion analysis identified a target site for Rep protein repression of FLP that is also repeated in the STB locus, suggesting this as the sequence required for Rep protein association with both regions of the plasmid. Distinct roles for Rep1 and Rep2 were identified; Rep1 was found to depend on Rep2 for post-translational stability, with Rep2 dependent on Rep1 for stable association with STB. Lysine-to-arginine substitutions in Rep1 and Rep2 impaired their association with the host covalent-modifier protein SUMO, suggesting these were sites of sumoylation. The substitutions did not affect interaction of the Rep proteins with each other or their stability but did perturb plasmid inheritance, suggesting that Rep protein sumoylation contributes to their plasmid partitioning function. When Rep1 was mutant, both Rep proteins lost their normal localization to the nuclear foci where 2-micron plasmids cluster, and were impaired for association with STB, supporting this as the cause of defective plasmid inheritance. The potential sumoylation-dependent association of the Rep proteins with the 2-micron plasmid partitioning locus suggests the plasmid has acquired a strategy common to eukaryotic viral and host genomes that depend on sumoylation of their segregation proteins for faithful inheritance. Collectively, my results shed light on how the 2-micron plasmid maintains the delicate balance of persisting without harming its host.

SUMO

chromosome segregation

post-translational modification

protein phosphorylation

gene expression

Molecular genetic analysis of receptor-defective androgen resistance in man

Prior, Lynn

January 1989

No description available.

Androgens -- Receptors.

Sex differentiation disorders.

X chromosome -- Abnormalities.