Epigenetic Regulation and Reprogramming of the H19 Imprinting Control Region

Mariano, Piero

January 2006

The development of a new individual from the fertilized oocyte can ultimately be seen as the consequence of the establishment and maintenance of specific patterns of gene expression. Although regulation of gene activity occurs at different levels, cellular specialization and differentiation are the results of developmental cues that essentially take place at the transcriptional level. The involvement of epigenetics in this process has become increasingly clear during the last decade. Imprinted genes constitute an excellent example as monoallelic expression seems to reflect differential epigenetic marks on the two alleles. This is the case of the imprinted H19 and Igf2 genes were the monoallelic expression is coordinated through a differentially methylated region (hypermethylated on the paternal allele), known as ICR (imprinted control region). In the mouse the ICR harbours four binding sites for the methylation sensitive insulator protein CTCF. Previous studies with episomal constructs had shown that this region behaved as an insulator and that CTCF is required for the insulator activity of the H19 ICR This thesis establish a clear link between the insulator function and the chromatin structure at the H19 ICR and indicates that the precise allocation of the CTCF target sites in the linker regions can play a critical role in this process. The importance of the CTCF interaction at the ICR was also confirmed in vivo using a mouse model that showed how intact CTCF target sites are needed to manifest insulator activity and methylation protection. We have investigated the role of CTCF and a related protein BORIS in establishing the maternal to paternal imprint transition in chromatin structure at the H19/Igf2 locus in the male germline. This thesis also describe the development of a new technique for the localization of chromatin associated factors and modifications with higher sensitivity and resolution compared to existing approaches.

Developmental biology

Imprinting

chromatin

H19

Igf2

CTCF

Insulator

methylation

Boris

Utvecklingsbiologi

Developmental biology

Utvecklingsbiologi

Epigenetic Regulation of Genomic Imprinting and Higher Order Chromatin Conformation / Epigenetisk reglering av genetisk prägling och kromatinets konformation

Tavoosidana, Gholamreza

January 2006

The genetic information encoded by the DNA sequence, can be expressed in different ways. Genomic imprinting is an epigenetic phenomenon that results in monoallelic expression of imprinted genes in a parent of origin-dependent manner. Imprinted genes are frequently found in clusters and can share common regulatory elements. Most of the imprinted genes are regulated by Imprinting Control Regions (ICRs). H19/Igf2 region is a well known imprinted cluster, which is regulated by insulator function of ICR located upstream of the H19 gene. It has been proposed that the epigenetic control of the insulator function of H19 ICR involves organization of higher order chromatin interactions. In this study we have investigated the role of post-translational modification in regulating insulator protein CTCF (CCCTC-binding factor). The results indicated novel links between poly(ADP-ribosyl)ation and CTCF, which are essential for regulating insulators function. We also studied the higher order chromatin conformation of Igf2/H19 region. The results indicated there are different chromatin structures on the parental alleles. We identified CTCF-dependent loop on the maternal allele which is different from the paternal chromatin and is essential for proper imprinting of Igf2 and H19 genes. The interaction of H19 ICR with Differentially Methylated Regions (DMRs) of Igf2 in a parent-specific manner maintains differential epigenetic marks on maternal and paternal alleles. The results indicate that CTCF occupies specific sites on highly condensed mitotic chromosomes. CTCF-dependent long-range key interaction on the maternal allele is maintained during mitosis, suggesting the possible epigenetic memory of dividing cells. In this study, we developed a new method called Circular Chromosome Conformation Capture (4C) to screen genome-wide interactions with H19 ICR. The results indicated there are wide intra- and inter-chromosomal interactions which are mostly dependent on CTCF-binding site at H19 ICR. These observations suggest new aspects of epigenetic regulation of the H19/Igf2 imprinted region and higher order chromatin structure.

Developmental biology

Epigenetic

Imprinting

Chromatin

CTCF

H19 ICR

4C

Utvecklingsbiologi

Biology

Biologi

Long Noncoding RNA Mediated Regulation of Imprinted Genes

Mohammad, Faizaan

January 2010

Genomic imprinting is an epigenetic phenomenon that causes a subset of mammalian genes to be expressed from only one allele in a parent-of-origin manner. The defects in the imprinting regulation result in disorders that affect development, growth and metabolism. We have used the Kcnq1 imprinted cluster as a model to understand the mechanism of imprinted gene regulation. The imprinting at the Kcnq1 locus is regulated by a long noncoding RNA, Kcnq1ot1, whose transcription on the paternal chromosome is associated with the silencing of at least eight neighboring genes. By destabilizing Kcnq1ot1 in an episomal system, we have conclusively shown that it is the RNA and not the process of transcription that is required for the gene silencing in cis. Kcnq1ot1 RNA interacts with the chromatin modifying enzymes such as G9a and Ezh2 and recruits them to imprinted genes to establish repressive chromatin compartment and gene silencing. Using the episomal system, we have identified an 890 bp silencing domain (SD) at the 5’ end of Kcnq1ot1 RNA, which is required for silencing of neighboring reporter genes. The deletion of the SD in the mouse resulted in the relaxation of imprinting of ubiquitously imprinted genes (Cdkn1c, Kcnq1, Slc22a18, and Phlda2) as well as reduced DNA methylation over the somatic DMRs associated with the ubiquitously imprinted genes. Moreover, Kcnq1ot1 RNA interacts with Dnmt1 and recruits to the somatic DMRs and this recruitment was significantly affected in the SD mutant mice. By using a transgenic mouse, we have conditionally deleted Kcnq1ot1 promoter at different developmental stages and demonstrated that Kcnq1ot1 maintains imprinting of the ubiquitously imprinted genes by regulating DNA methylation over the somatic DMRs. Kcnq1ot1 is dispensable for the maintenance of repressive histone marks and the imprinting of placental-specific imprinted genes (Tssc4 and Osbpl5). In conclusion, we have described the mechanisms by which Kcnq1ot1 RNA establishes and maintains expression of multiple imprinted genes in cis.

Genomic imprinting

noncoding RNA

epigenetics

chromatin

DNA methylation

Developmental biology

Utvecklingsbiologi

Molecular biology

Molekylärbiologi

Disruption of Epigenetic Regulatory Elements and Chromosomal Alterations in Patients with Beckwith-Wiedemann Syndrome

Smith, Adam Campbell

03 March 2010

Genomic imprinting refers to the parent-of-origin specific monoallelic expression of a gene. Imprinted genes are often clustered in the genome and their expression is regulated by an imprinting centre (IC). ICs are regions of DNA that propagate the parental specific regulation of gene expression, which are usually characterized by differential DNA methylation, histone marks and the presence of non-coding RNAs. Beckwith-Wiedemann syndrome (BWS) is an overgrowth syndrome associated with the dysregulation of imprinted gene expression on human chromosome band 11p15.5. The 11p15.5 imprinted region has two imprinting centres, IC1 and IC2. IC1 is telomeric and regulates the imprinted expression of the genes H19 and IGF2. IC2 is ~700kb centromeric and is associated with a cluster of nine imprinted genes including CDKN1C, KCNQ1 and an imprinted non-coding RNA associated with IC2, KCNQ1OT1. Loss of differential DNA methylation at IC2 is seen in 50% of patients with BWS with loss of imprint of the non-coding RNA KCNQ1OT1 and associated with a decreased expression of the putative tumour suppressor CDKN1C. Patients with BWS also have a thousand-fold increased risk of pediatric cancer. The focus of this thesis involves investigation of dysregulation of imprinting in three groups of BWS patients. Firstly, I show that BWS patients with alveolar rhabdomyosarcoma have constitutional loss of methylation at IC2 and biallelic expression of KCNQ1OT1. Secondly, loss of methylation at IC2 has been previously associated with female monozygotic twins discordant for BWS. In male monozygotic twins with BWS, however, the molecular lesions reflect the molecular heterogeneity seen in BWS singletons. Thirdly, BWS patients associated with translocations and inversions that have breakpoints within the KCNQ1 gene near IC2 show regional gain of DNA methylation around the breakpoint and decreased expression of CDKN1C. Therefore, using a rare collection of BWS patients, I have attempted to determine the various roles of the imprinting centres IC1 and IC2 and their involvement in tumourigenesis, monozygotic twinning and structural chromosomal rearrangements causing BWS.

Genomic Imprinting

Epigenetics

Beckwith-Wiedemann syndrome

DNA Methylation

Cytogenetics

Rhabdomyosarcoma

Monozygotic Twins

0369

Disruption of Epigenetic Regulatory Elements and Chromosomal Alterations in Patients with Beckwith-Wiedemann Syndrome

Smith, Adam Campbell

03 March 2010

Genomic imprinting refers to the parent-of-origin specific monoallelic expression of a gene. Imprinted genes are often clustered in the genome and their expression is regulated by an imprinting centre (IC). ICs are regions of DNA that propagate the parental specific regulation of gene expression, which are usually characterized by differential DNA methylation, histone marks and the presence of non-coding RNAs. Beckwith-Wiedemann syndrome (BWS) is an overgrowth syndrome associated with the dysregulation of imprinted gene expression on human chromosome band 11p15.5. The 11p15.5 imprinted region has two imprinting centres, IC1 and IC2. IC1 is telomeric and regulates the imprinted expression of the genes H19 and IGF2. IC2 is ~700kb centromeric and is associated with a cluster of nine imprinted genes including CDKN1C, KCNQ1 and an imprinted non-coding RNA associated with IC2, KCNQ1OT1. Loss of differential DNA methylation at IC2 is seen in 50% of patients with BWS with loss of imprint of the non-coding RNA KCNQ1OT1 and associated with a decreased expression of the putative tumour suppressor CDKN1C. Patients with BWS also have a thousand-fold increased risk of pediatric cancer. The focus of this thesis involves investigation of dysregulation of imprinting in three groups of BWS patients. Firstly, I show that BWS patients with alveolar rhabdomyosarcoma have constitutional loss of methylation at IC2 and biallelic expression of KCNQ1OT1. Secondly, loss of methylation at IC2 has been previously associated with female monozygotic twins discordant for BWS. In male monozygotic twins with BWS, however, the molecular lesions reflect the molecular heterogeneity seen in BWS singletons. Thirdly, BWS patients associated with translocations and inversions that have breakpoints within the KCNQ1 gene near IC2 show regional gain of DNA methylation around the breakpoint and decreased expression of CDKN1C. Therefore, using a rare collection of BWS patients, I have attempted to determine the various roles of the imprinting centres IC1 and IC2 and their involvement in tumourigenesis, monozygotic twinning and structural chromosomal rearrangements causing BWS.

Genomic Imprinting

Epigenetics

Beckwith-Wiedemann syndrome

DNA Methylation

Cytogenetics

Rhabdomyosarcoma

Monozygotic Twins

0369

Characterizations of spatio-temporal complex systems

Krishan, Kapilanjan

20 May 2005

The thesis develops two characterizations of spatio-temporal complex patterns. While these are developed for the patterns of fluid flow in experiments on Rayleigh-Benard Convection(RBC), they are adaptable to a wide range of spatially extended systems. The characterizations may be especially useful in cases where one does not have good models describing the dynamics, making numerical and analytic studies difficult. In Spiral Defect Chaos(SDC), a weakly turbulent regime of RBC, the convective rolls exhibit complex spatial and temporal dynamics. We study the dynamics of SDC through local defect formations between convective rolls as well as the topological rearrangements of these rolls at a global scale. A laser based thermal actuation system is developed to reproducibly impose initial states for the fluid flow and construct ensembles of trajectories in the neighborhood of defect nucleation. This is used to extract the modes and their growth rates, characterizing the linear manifold corresponding to defect nucleation. The linear manifold corresponding to instabilities resulting in defect formation is key to building efficient schemes to control the dynamics exhibited. We also develop the use of computational homology as a tool to study spatially extended dynamical systems. A quantitative measure of the topological features of patterns is shown to provide insights into the underlying dynamics not easily uncovered otherwise. In the case of RBC, the homology of the patterns is seen to indicate asymmetries between hot and cold regions of the flow, stochastic evolution at a global scale as well as bifurcations occurring well into the turbulent regime of the flow.

Spatio-temporal dynamics

Homology

Rayleigh-Benard convection

Spiral defect chaos

Thermal imprinting

Topology

Novel Polymer-Metal Nanocomposites for Applications in Detection and Sensing

Chaparro, Dayling L.

11 April 2007

Detection of trace elements such as organic contaminants, explosive residues, and metal ions is an intellectually challenging task in science and engineering. It is also a topic of increasing importance due to its impact on society and the environment. Designing molecularly imprinted materials is one of the most promising approaches to explore sensing and detection applications. “Stimuli-sensitive” polymer materials are ideal candidates for these imprinted sensors as they are able to respond to changes in their environment and can be tailored by cross-linking the polymer chains. The responses can be amplified and transduced into measurable signals due to macromolecular properties provided by the use of a polymer. The purpose of the research in this project is to combine organic polymers with inorganic constituents to tailor the binding properties and the responses of the composite material for detection of metals ions in aqueous solutions. The research, here, is based on a thermally responsive polymer such as poly(Nisopropylacrylamide) (PNIPAM), which exhibits a well-known reversible volume phase transition in aqueous media around approximately 32°C. Combining cross-linked microgels formed from PNIPAM and its copolymers with gold nanoparticles (GNP) imparts the composite material with optical properties such as intense visible absorption due to the unique surface plasmon absorption of these small nanoparticles. The use of copolymers allows incorporation of functional groups, such as carboxylic acid, that are potential sites for binding metal ions. Cross-linking of the metal ion binding polymer imprints the metal ion in the PNIPAM microgel network. In this research, design of the composite material was investigated using copolymers of NIPAM and acrylic acid (AA), copolymers of NIPAM and glycidyl methacrylate (GMA), and interpenetrating networks of PNIPAM and PAA. A broad spectrum of polymerization conditions were studied such as changes in cross-linking density as well as changes in the synthetic procedure. Techniques such as turbidometry, ultraviolet visible spectroscopy (UV-VIS), transmission electron microscopy (TEM), and dynamic light scattering (DLS) were employed to characterize the microgels as well as their composites with GNP. Preliminary investigation of imprinting the microgels with heavy metal ions such as copper was also performed. The novel polymer-metal nanocomposites explored here will serve as an important contribution for the current ongoing research efforts in designing materials in the nano-scale capable of sensing and detecting metal ions in solution with high selectivity.

pnipam

microgels

gold nanoparticles

molecular imprinting

interpenetrated networks

American Studies

Arts and Humanities

Automatic solid-phase synthesis of molecularly imprinted nanoparticles (MIP NPs)

Poma, Alessandro

January 2012

Molecularly Imprinted Polymers (MIPs) are potential generic alternatives to antibodies in diagnostics and separations. To compete with biomolecules in these technological niches, MIPs need to share the characteristics of antibodies (solubility, size, specificity and affinity) whilst maintaining the advantages of MIPs (low cost, short development time and high stability). For this reason the interest in preparing MIPs as nanoparticles (MIP NPs) has increased exponentially in the last decade. Cont/d.

660.6

The role of sexual imprinting in speciation: lessons from deer mice (genus Peromyscus)

Kay, Emily Ho

21 October 2014

Sexual imprinting, the process of learning mate preferences at a young age, could promote speciation by reducing attraction to individuals from divergent populations or species, consequently creating or maintaining reproductive isolation. Yet, despite the documentation of sexual imprinting in many taxa, its connection to speciation has been understudied. I chose to explore the potential link between sexual imprinting and reproductive isolation and in two North American rodents--the white-footed mouse (Peromyscus leucopus) and its sister species, the cotton mouse (Peromyscus gossypinus). These species have overlapping distributions in nature, possibly allowing interbreeding and admixture. In Chapter 1, I used double-digest restriction-associated DNA sequencing to test for hybridization in sympatric natural populations and found that 1.5% of sampled individuals showed evidence of admixture yet the species have maintained genetic distinctness in sympatry. In the lab, the species hybridize when given no choice of mates but mate more readily with conspecifics, suggesting that mating preferences may prevent hybridization in the wild. In Chapter 2, I tested whether mating preferences create significant reproductive isolation. I measured mating preferences in controlled laboratory conditions and found that both species and sexes preferred conspecific to heterospecific mates in 85% of trials. I then raised offspring with foster parents of the opposite species and found that P. leucopus has a genetically-determined preference while P. gossypinus learns its preference. In Chapter 3, I tested whether sexual imprinting on parental diet could generate assortative mating within a species. I tested this hypothesis by feeding P. gossypinus parents either orange- or garlic-flavored water, thereby exposing their offspring to these flavors through their parents until weaning. I tested the preferences of these offspring as adults and found that P. gossypinus, especially females, had strong assortative mating preferences. This implies that at least females learn parental dietary information and that assortative mating could evolve within a single generation. Together, my results confirm that sexual imprinting on parental traits--possibly mediated through dietary differences--can create assortative mating capable of generating sexual isolation and reducing gene flow between species. My research supports the importance of mating preferences and learning in speciation.

Biology

Evolution & development

Behavioral sciences

mate preference

Peromyscus

rodent

sexual imprinting

sexual isolation

speciation

Consequences of mitotic loss of heterozygosity on genomic imprinting in mouse embryonic stem cells

Elves, Rachel Leigh

11 1900

Epigenetic differences between maternally inherited and paternally inherited chromosomes, such as CpG methylation, render the maternal and paternal genome functionally inequivalent, a phenomenon called genomic imprinting. This functional inequivalence is exemplified with imprinted genes, whose expression is parent-of-origin specific. The dosage of imprinted gene expression is disrupted in cells with uniparental disomy (UPD), which is an unequal parental contribution to the genome. I have derived mouse embryonic stem (ES) cell sub-lines with maternal UPD (mUPD) for mouse chromosome 6 (MMU6) to characterize regulation and maintenance of imprinted gene expression. The main finding from this study is that maintenance of imprinting in mitotic UPD is extremely variable. Imprint maintenance was shown to vary from gene to gene, and to vary between ES cell lines depending on the mechanism of loss of heterozygosity (LOH) in that cell line. Certain genes analyzed, such as Peg10, Sgce, Peg1, and Mit1 showed abnormal expression in ES cell lines for which they were mUPD. These abnormal expression levels are similar to that observed in ES cells with meiotically-derived full genome mUPD (parthenogenetic ES cells). Imprinted CpG methylation at the Peg1 promoter was found to be abnormal in all sub-lines with mUPD for Peg1. Two cell sub-lines which incurred LOH through mitotic recombination showed hypermethylation of Peg1, consistent with the presence of two maternal alleles. Surprisingly, a cell sub-line which incurred LOH through full chromosome duplication/loss showed hypomethylation of Peg1. The levels of methylation observed in these sub-lines correlates with expression, as the first two sub-lines showed a near-consistent reduction of Peg1, while the latter showed Peg1 levels close to wild-type. Altogether these results suggest that certain imprinted genes, like Peg1 and Peg10, have stricter imprinting maintenance, and as a result show abnormal expression in UPD. This strict imprint maintenance is disrupted, however, in UPD incurred through full chromosome duplication/loss, possibly because of the trisomic intermediate stage which occurs in this mechanism.

Genomic imprinting

Loss of heterozygosity

Embryonic stem cells

Mouse chromosome 6

Peg1

Mest