INTER-KINGDOM EPIGENETICS: CHARACTERIZATION OF MAIZE B1 TANDEM REPEAT-MEDIATED SILENCING IN DROSOPHILA MELANOGASTER

McEachern, Lori A.

19 August 2010

Transgenic organisms are a valuable tool for studying epigenetics, as they provide significant insight into the evolutionary conservation of epigenetic control sequences, the interacting proteins, and the underlying molecular mechanisms. Paramutation is an epigenetic phenomenon in which the epigenetic status and expression level of one allele is heritably altered after pairing with another. At the b1 locus in maize, a control region consisting of seven 853 bp tandem repeats is required for paramutation. To study the conservation of the epigenetic mechanisms underlying maize b1 paramutation, I created transgenic Drosophila carrying the maize b1 control region flanked by FRT sites and adjacent to the Drosophila white reporter gene. The maize b1 tandem repeats caused epigenetic silencing in Drosophila, as white expression consistently increased following repeat removal. A single copy of the tandem repeat sequence was sufficient to cause silencing, and silencing strength increased as the number of repeats increased. Trans interactions, such as pairing-sensitive silencing, were also observed and appear to require a threshold number of b1 tandem repeats, similar to paramutation in maize. Analysis of transcription from the repeats showed that the b1 tandem repeats are transcribed from both strands in Drosophila, as they are in maize. Bidirectional transcription was found to extend to the regions flanking the repeats, and persisted in “repeats-out” transgenes following repeat removal. However, aberrant transcription was lost when a zero-repeat transgene was moved to a new genomic position, suggesting that it may be due to an epigenetic mark that is retained from the previous silenced state. A search for modifiers of b1 repeat-mediated silencing demonstrated that Polycomb group proteins are involved. Together, these results indicate considerable conservation of an epigenetic silencing process between the plant and animal kingdoms. Genomic imprinting is a related epigenetic process in which parent-specific epigenetic states are inherited and maintained in progeny. The conservation of epigenetic mechanisms was further explored via an in-depth review of the molecular mechanisms underlying genomic imprinting in plants, mammals and insects, and identification of potentially imprinted genes in Drosophila by microarray analysis.

Epigenetics

Drosophila melanogaster

Paramutation

Tandem repeats

Transcription

Silencing

Genomic imprinting

The three-dimensional (3D) organization of telomeres during cellular transformation

Chuang, Tony Chih-Yuan

22 September 2010

Statement of Problem Telomere dynamics in the three-dimensional (3D) space of the mammalian nucleus plays an important role in the maintenance of genomic stability. However, the telomere distribution in 3D nuclear space of normal and tumor cells was unknown when the study was initiated. Methods Telomere fluorescence in situ hybridization (FISH) and 3D molecular imaging, deconvolution, and analysis were used to investigate telomere organization in normal, immortalized and tumor cells from mouse and human cell lines, and primary tissues. Results Telomeres are organized in a non-overlapping manner and in a cell-cycle dependant fashion in normal cells. In the late G2 phase of cell cycle, telomeres are assembled into a flattened sphere that is termed the telomeric disk In contrast, the telomeric disk is disrupted in the tumor cells. Moreover, telomeric aggregates (TAs) are found in tumor cells. Conditional c-Myc over-expression induces telomeric aggregation leading to the onset of breakage-bridge-fusion cycles and subsequent chromosomal abnormality. Conclusions Telomeres are distributed in a nonrandom and dynamic fashion in the 3D space of a normal cell. Telomeric aggregates are present in cells with genomic instability such as tumor cells and cells with deregulation of c-Myc. Consequently, TA can be a useful biomarker for research in cancer and other disease processes.

telomere

c-myc

deconvolution

molecular imaging

genomic instability

biomarker

Molecular Studies in Horses with SRY-Positive XY Sex Reversal

Fang, Erica

2011 December 1900

Sex determination in mammals is regulated by the sex-determining region on the Y chromosome (SRY); the presence of SRY activates the male developmental pathway and suppresses the gene network necessary for female gonad development. Mutations in sex determination genes lead to various abnormal sexual phenotypes, including sex reversal syndrome in which the genetic and phenotypic sex do not match. Sex reversal syndrome has been reported in humans, mouse, and several domestic species. In horses, SRY-negative XY sex reversal syndrome has been well described and is caused by deletions on the Y chromosome. However, the molecular causes of the SRY-positive condition in horses and other mammals are not known. This research investigated five horses affected with SRY-positive XY sex reversal syndrome. Sequencing of the coding exon region of the SRY gene in the five cases showed 99-100% alignment with the sequences of normal males. Genotyping of two closely related individuals with 46 normal male controls on an equine SNP50 Beadchip identified two statistically significant SNPs in a ~16 Mb region on the long arm of horse chromosome 3 (ECA3q). The region was analyzed using Gene Ontology (GO) and Gene Relationships Across Implicated Loci (GRAIL) to select functionally relevant candidate genes for sequencing. Further analysis of the entire horse genome was done through array comparative genomic hybridization (aCGH), which investigated possible structural rearrangements, such as copy number variants (CNVs). Deletions of olfactory receptor genes were detected on multiple chromosomes and confirmed through quantitative real-time PCR (qPCR). A homozygous deletion on ECA29 in a region containing genes of the aldo-keto reductase gene family, known to play a role in interconverting sex hormones between active forms and inactive forms, was discovered in two sex reversed animals. The findings were confirmed through qPCR and fluorescence in situ hybridization (FISH), and experiments to define the specific breakpoints of the deletion through PCR have been initiated. This research represents the first systematic search in the horse genome for mutations and CNVs related to sex determination. The findings contribute to better understanding of the molecular mechanisms of sex determination in horses and other mammals, including humans.

Horses

SRY

Sex Reversal

SNP analysis

array comparative genomic hybridization

Investigating the Transcriptional Basis of Genome Elimination by a ‘Selfish’ B Chromosome in Nasonia vitripennis

Kaeding, Kelsey E

01 January 2015

Genomes usually work together to promote the fitness of the organism, but sometimes parts of the genome cause intragenomic conflict, and act selfishly in order to promote their transmission. An example of this conflict is a selfish B chromosome known as paternal sex ratio (PSR) in the jewel wasp Nasonia vitripennis. Transmitted solely to new progeny with the sperms hereditary material, PSR completely destroys the paternal genome during the first mitotic division of the newly fertilized embryo. This effect enhances transmission of the PSR chromosome because of the unique haplodiploid reproductive mode of Nasonia and other members of the hymenopteran insect group. Through transcriptomic analyses, our group recently discovered that the PSR chromosome expresses eleven transcripts in the wasp testis. A plausible hypothesis is that one or more of these transcripts play some role in paternal genome elimination. In this study I have begun to test this hypothesis by screening through a set of previously produced truncated versions of the PSR chromosome. Specifically, I used PCR in order to screen these truncated chromosomes for the presence of each of these PSR-specific transcripts. I could then correlate the level of genome elimination induced by each truncated PSR chromosome with the presence or absence of the expressed transcripts. My work has established that (i) three of the eleven transcripts are likely not involved in genome elimination; (ii) no single transcript alone causes genome elimination; (iii) the remaining eight of eleven transcripts are viable candidates for causing genome elimination; and (iv) it is likely that a sub-group of these transcripts may operate together to induce this effect. I discuss several models in which PSR-expressed RNA molecules could operate to cause genome elimination.

B chromosome

PSR

Nasonia vitripennis

genomic conflict

Biology

HUMAN RIBOSOMAL RNA GENE CLUSTERS ARE RECOMBINATIONAL HOTSPOTS IN CANCER

Stults, Dawn Michelle

01 January 2009

The gene that produces the precursor RNA transcript to the three largest ribosomal RNA molecules (rDNA) is present in multiple copies and organized into gene clusters. They represent 0.5% of the diploid human genome but are critical for cellular viability. The individual genes possess very high levels of sequence identity and are present in high local concentration, making them ideal substrates for genomic rearrangement driven by dysregulated homologous recombination. Our laboratory has developed a sensitive physical assay capable of detecting recombination-mediated genomic restructuring in the rDNA by monitoring changes in lengths of the individual clusters. In order to determine whether dysregulated recombination is a potential driving force of genomic instability in human cancer, adult patients with either lung or colorectal cancer, and pediatric patients with leukemia were prospectively recruited and assayed. Over half of the adult solid tumors show detectable rDNA rearrangements relative to either surrounding non-tumor tissue or normal peripheral blood. In contrast, there is a greatly reduced frequency of alteration in pediatric leukemia. This finding makes rDNA restructuring one of the most common chromosomal alterations in adult solid tumors, illustrates the dynamic plasticity of the human genome, and may have prognostic or predictive value in disease progression.

genomic instability

cancer

gene clusters

DNA repair

recombination

Genetic Phenomena

The three-dimensional (3D) organization of telomeres during cellular transformation

Chuang, Tony Chih-Yuan

22 September 2010

Statement of Problem Telomere dynamics in the three-dimensional (3D) space of the mammalian nucleus plays an important role in the maintenance of genomic stability. However, the telomere distribution in 3D nuclear space of normal and tumor cells was unknown when the study was initiated. Methods Telomere fluorescence in situ hybridization (FISH) and 3D molecular imaging, deconvolution, and analysis were used to investigate telomere organization in normal, immortalized and tumor cells from mouse and human cell lines, and primary tissues. Results Telomeres are organized in a non-overlapping manner and in a cell-cycle dependant fashion in normal cells. In the late G2 phase of cell cycle, telomeres are assembled into a flattened sphere that is termed the telomeric disk In contrast, the telomeric disk is disrupted in the tumor cells. Moreover, telomeric aggregates (TAs) are found in tumor cells. Conditional c-Myc over-expression induces telomeric aggregation leading to the onset of breakage-bridge-fusion cycles and subsequent chromosomal abnormality. Conclusions Telomeres are distributed in a nonrandom and dynamic fashion in the 3D space of a normal cell. Telomeric aggregates are present in cells with genomic instability such as tumor cells and cells with deregulation of c-Myc. Consequently, TA can be a useful biomarker for research in cancer and other disease processes.

telomere

c-myc

deconvolution

molecular imaging

genomic instability

biomarker

The role of acyl carrier protein in strawberry fruit ripening

Themis, Matthew

January 2000

Strawberry (Fragaria ananassa) is an economically important soft fruit that is highly valued as a fresh product and flavouring. During ripening, strawberry fruits undergo a number of physiological changes affecting colour, texture and flavour. An understanding of these changes at the biochemical and molecular level will be important in developing strategies for enhancing the quality attributes of this fruit. A cDNA encoding a ripening- enhanced acyl carrier protein (RE-ACP) was previously isolated from strawberry fruit. AC? is an essential component of fatty acid synthesis in both plants and animals. The aims of this thesis were to isolate and characterise this and other members of the ACP multigene family expressed in strawberry fruit. Six closely related putative AC? cDNA isoforms were identified from strawberry. Two of these were obtained by screening a cDNA library from ripe fruit and three were obtained by a technique known as candidate fragment length polymorphism (CFLP) that utilised ACP gene-specific primers for AFLP-cDNA display. Northern analysis was not able to differentiate their expression but ACP was highly up-regulated in ripening fruit whereas low levels of expression were detected in other strawberry tissues, including achenes (seeds), expanding leaves and flowers. The RE-ACP was over-expressed in E. coli and the recombinant protein partially purified. The over-expressed protein had a M(_r) of 20kDa on SDS-PAGE and appeared to form a dimer. A genomic library was constructed from F. ananassa from which two different genomic clones closely related to RE-ACP were obtained. Promoter analysis indicated the presence of regulatory elements. The characterization of putative ACP cDNA and genomic clones, including the 5' upstream regions, is described and their possible role in strawberry fruit is discussed. Key words: Strawberry, fruit, ripening, gene expression, genomic, cDNA, fatty acid, acyl carrier protein, aroma, promoter.

572.8

Effect of Bcl-2 on the cellular response to oxidative stress

Cox, Andrew Graham

January 2006

Exposure of cells to hydrogen peroxide can cause oxidative damage to cellular constituents including lipids, protein, and DNA. At elevated concentrations, hydrogen peroxide can trigger cell death by apoptosis or necrosis. Apoptotic cell death can be prevented by overexpression of the oncoprotein Bcl-2. The exact mechanism by which Bcl-2 blocks cell death is controversial. Some researchers believe that Bcl-2 possesses antioxidant properties that protect cells from apoptosis. The purpose of this thesis was to assess oxidative stress and apoptosis following hydrogen peroxide exposure in Jurkat T cells overexpressing Bcl-2. One of the major objectives was to ascertain whether or not Bcl-2 overexpression elevated the antioxidant capacity of Jurkat T cells to provide protection from oxidant-induced cell death. Hydrogen peroxide treated Jurkat cells became apoptotic at moderate levels of oxidant (25-100 uM H2O2), and necrotic at higher doses (greater than 200 uM H2O2). Bcl-2 overexpression prevented caspase activation and cell death at the apoptotic doses of H2O2, but not the necrotic doses. Caspase inhibition studies demonstrated that Bcl-2 overexpression provided a greater level of resistance from H2O2-induced cell death than the broad-spectrum caspase inhibitor z-VAD.fmk. A systematic study was carried out examining the antioxidant status of Jurkat cells overexpressing Bcl-2. Several Bcl-2 transfectants were utilised for the study, so that any differences seen could be correlated to the level of Bcl-2 expression. Surprisingly, there were no statistically significant differences among the Bcl-2 transfectants for any of the antioxidant enzymes. Jurkat cells overexpressing Bcl-2 exhibited the same level of oxidative damage to lipids and protein in response to H2O2 exposure as the parental Jurkat cells. Interestingly, Jurkat cells overexpressing Bcl-2 continued to grow in culture after H2O2 exposure, despite harboring damage to cellular constituents. Consistent with these results, H2O2 treated Jurkat cells overexpressing Bcl-2, which failed to undergo apoptosis, were more prone to genomic instability. Together, these findings suggest that Bcl-2 overexpression protects Jurkat cells from H2O2-induced cell death by blocking apoptosis. Jurkat cells overexpressing Bcl-2 were no better at detoxifying oxidants and showed the same level of oxidative damage following H2O2 exposure. As a result, the overexpression of Bcl-2 considerably enhanced the mutagenicity of H2O2.

Bcl-2

antioxidant

oxidative stress

apoptosis

genomic instability

Studies of fusion oncogenes and genomic imbalances in human tumors /

Persson, Fredrik,

January 2007

Diss. (sammanfattning) Göteborg : Univ. , 2007. / Härtill 4 uppsatser.

Genomic instability, gene expression and prognosis in breast cancer /

Kronenwett, Ulrike,

January 2005

Diss. (sammanfattning) Stockholm : Karol. inst., 2005. / Härtill 5 uppsatser.