Global ETD Search

21	CTCF and Epigenetic Regulation of the <i>H19/Igf2</i> Locus Pant, Vinod January 2003 (has links) <p>An overall coordination between the expressions of genes is required for the proper development of an individual. Although most genes are expressed from both the constituent alleles of the genome, a small subset of autosomal genes are preferentially expressed from only one of the parental alleles, a phenomenon known as genomic imprinting. </p><p>The imprinted <i>H19</i> and <i>Igf2</i> genes are considered paradigms of genomic imprinting as their monoallelic expression pattern is coordinated by a short stretch of sequence located upstream of <i>H19</i>, known as the imprinting control region (ICR). This region shows differential methylation, with hypermethylation specifically on the paternal allele. On the maternal allele this region acts as an insulator and harbours maternal specific hypersensitive sites. </p><p>The hypersensitive sites were identified as the result of association of the vertebrate insulator protein CTCF with the region. This association was investigated in both an <i>in vitro</i> episomal system and in an <i>in vivo</i> mouse model system by mutating the CTCF target sites at the <i>H19</i> ICR. The importance of CTCF for the insulator property of the region was confirmed in both instances. In the mouse model, the disruption of the binding was also observed to affect the methylation profile of the ICR, which ultimately resulted in the de-repression of the maternal <i>Igf2</i> allele.</p><p>The relevance of multiple CTCF target sites in higher vertebrates for the proper insulator function was investigated using another knock-in mouse model with mutation at a single CTCF target site in the <i>H19</i> ICR. The investigation confirmed the cooperation between the target sites for the establishment of a functional insulator on the maternal allele. Target sites in the ICR were also analysed for their differential binding affinity for the CTCF protein.</p><p>The utilisation of the CTCF target sites was examined in different human tumours and cell lines. Methylation analysis conveyed a lack of correlation between the loss of insulator function and methylation status of the ICR with the loss of imprinting (LOI) of <i>IGF2</i>. Investigations also identified a novel mechanism, which neutralised the chromatin insulator function of the <i>H19</i> ICR without affecting its chromatin conformation. This principle might also help in explaining the loss of <i>IGF2</i> imprinting observed in some instances.</p><p>In conclusion, this thesis confirms the importance of CTCF in the formation of an epigenetically regulated chromatin insulator at the ICR, which in turn controls the expression pattern of <i>H19</i> and <i>Igf2</i>. The studies also confirm the role of CTCF in the maintenance of the methylation profile of the region. Investigations into the loss of <i>IGF2 </i>imprinting in human cancer indicate the involvement of other novel mechanisms besides CTCF in the regulation of insulator function.</p> Developmental biology Imprinting Chromatin H19 Igf2 CTCF Insulator methylation Utvecklingsbiologi Developmental biology Utvecklingsbiologi
22	Chromatin Insulators and CTCF: Architects of Epigenetic States during Development. Mukhopadhyay, Rituparna January 2004 (has links) <p>A controlled and efficient coordination of gene expression is the key for normal development of an organism. In mammals, a subset of autosomal genes is expressed monoallelically depending on the sex of the transmitting parent, a phenomenon known as genomic imprinting.</p><p>The imprinted state of the <i>H19</i> and <i>Igf2</i> genes is controlled by a short stretch of sequences upstream of <i>H19</i> known as the imprinting control region (ICR). This region is differentially methylated and is responsible for the repression of the maternally inherited <i>Igf2</i> allele. It harbors hypersensitive sites on the unmethylated maternal allele and functions as an insulator that binds a chromatin insulator protein CTCF. Hence the <i>H19</i> ICR, which plays an important role in maintaining the imprinting status of <i>H19</i> and <i>Igf2</i>, was shown to lose the insulator property upon CpG methylation.</p><p>Another ICR in the <i>Kcnq1</i> locus regulates long-range repression of <i>p57Kip2</i> and <i>Kcnq1</i> on the paternal allele, and is located on the neighboring subdomain of the imprinted gene cluster containing <i>H19</i> and <i>Igf2</i>, on the distal end of mouse chromosome 7. Similarly to the <i>H19</i> ICR, the <i>Kcnq1</i> ICR appears to possess a unidirectional and methylation-sensitive chromatin insulator property in two different somatic cell types. Hence, methylation dependent insulator activity emerges as a common feature of imprinting control regions.</p><p>The protein CTCF is required for the interpretation and propagation of the differentially methylated status of the <i>H19</i> ICR. Work in this thesis shows that this feature applies genomewide. The mapping of CTCF target sites demonstrated not only a strong link between CTCF, formation of insulator complexes and maintaining methylation-free domains, but also a network of target sites that are involved in pivotal functions. The pattern of CTCF <i>in vivo</i> occupancy varies in a lineage-specific manner, although a small group of target sites show constitutive binding. </p><p>In conclusion, the work of this thesis shows that epigenetic marks play an important role in regulating the insulator property. The studies also confirm the importance of CTCF in maintaining methylation-free domains and its role in insulator function. Our study unravels a new range of target sites for CTCF involved in divergent functions and their developmental control.</p> Developmental biology DNA methylation CTCF Chromatin insulators Microarray Utvecklingsbiologi Developmental biology Utvecklingsbiologi
23	Transcriptional Silencing in the Imprinted Igf2-H19 Loci: The Mystique of Epigenetics Ginjala, Vasudeva January 2002 (has links) Genomic imprinting marks a subset of autosomal loci expressed in parent of origin-dependent monoallelic expression in a non-Mendelian fashion. To restore totipotency and to reset the imprint according to the sex of the individual, the mark must be erased during germline development. The imprinted Igf2-H19 loci located distally on chromosome 7 in mouse and 11p15.5 in human, share common regulatory elements that regulate differential expression. Where the H19 is silenced when paternally inherited, the Igf2 is silenced when maternally inherited. The differentially methylated 5'-flank of H19 gene, termed imprinting control region (ICR), shown to display a unique chromatin organisation harbours hypersensitive sites in linker regions flanked by positioned nucleosomes on the maternal allele. This unique chromatin conformation functions as a methylation-sensitive and unidirectional chromatin insulator, which later was found to depend on the chromatin insulator protein CTCF. The H19 ICR exhibits default-silencing functions in promoter-proximal positions. The maximal distance between the H19 ICR and the promoter of the reporter gene required for this effect was 1.2 ± 0.3kb which can be compared to the 1.9 kb distance between the endogenous H19 ICR and H19 promoter. Results suggest that the H19 ICR adopts a chromatin conformation that must be separated by a minimal distance from pivotal cis-regulatory elements to avoid adverse effects on neighbouring promoters. Poly(ADP-ribosy)lation represents a novel post-translational epigenetic mark that segregates with exclusively the maternal derived H19 ICR and associated with factors that interact with the CTCF target sites. CTCF is itself poly(ADP-ribosy)lated and the poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide relieves the insulator function of the H19 ICR. Designed zinc finger proteins were applied to examine if epigenetic marks provided an obstacle for targeted activation and silencing. The zinc finger protein ZFP809 with activator/repressor domain able to efficiently activate/silence the IGF2 target. Murine hybrid cell lines of human chromosome 11, demonstrated that the ZFP809 overcame the epigenetic marks that repressed maternal IGF2 and paternal H19 allele, respectively. Results suggested that imprinted genes are not normally exposed to strong cis-regulatory elements and that the designed ZFPs can be exploited to develop a therapeutic method for rectifying epigenetic lesions. Developmental biology Imprinting DNA methylation IGF2-H19 CTCF ZFPs PARP Utvecklingsbiologi Developmental biology Utvecklingsbiologi
24	CTCF and Epigenetic Regulation of the H19/Igf2 Locus Pant, Vinod January 2003 (has links) An overall coordination between the expressions of genes is required for the proper development of an individual. Although most genes are expressed from both the constituent alleles of the genome, a small subset of autosomal genes are preferentially expressed from only one of the parental alleles, a phenomenon known as genomic imprinting. The imprinted H19 and Igf2 genes are considered paradigms of genomic imprinting as their monoallelic expression pattern is coordinated by a short stretch of sequence located upstream of H19, known as the imprinting control region (ICR). This region shows differential methylation, with hypermethylation specifically on the paternal allele. On the maternal allele this region acts as an insulator and harbours maternal specific hypersensitive sites. The hypersensitive sites were identified as the result of association of the vertebrate insulator protein CTCF with the region. This association was investigated in both an in vitro episomal system and in an in vivo mouse model system by mutating the CTCF target sites at the H19 ICR. The importance of CTCF for the insulator property of the region was confirmed in both instances. In the mouse model, the disruption of the binding was also observed to affect the methylation profile of the ICR, which ultimately resulted in the de-repression of the maternal Igf2 allele. The relevance of multiple CTCF target sites in higher vertebrates for the proper insulator function was investigated using another knock-in mouse model with mutation at a single CTCF target site in the H19 ICR. The investigation confirmed the cooperation between the target sites for the establishment of a functional insulator on the maternal allele. Target sites in the ICR were also analysed for their differential binding affinity for the CTCF protein. The utilisation of the CTCF target sites was examined in different human tumours and cell lines. Methylation analysis conveyed a lack of correlation between the loss of insulator function and methylation status of the ICR with the loss of imprinting (LOI) of IGF2. Investigations also identified a novel mechanism, which neutralised the chromatin insulator function of the H19 ICR without affecting its chromatin conformation. This principle might also help in explaining the loss of IGF2 imprinting observed in some instances. In conclusion, this thesis confirms the importance of CTCF in the formation of an epigenetically regulated chromatin insulator at the ICR, which in turn controls the expression pattern of H19 and Igf2. The studies also confirm the role of CTCF in the maintenance of the methylation profile of the region. Investigations into the loss of IGF2 imprinting in human cancer indicate the involvement of other novel mechanisms besides CTCF in the regulation of insulator function. Developmental biology Imprinting Chromatin H19 Igf2 CTCF Insulator methylation Utvecklingsbiologi Developmental biology Utvecklingsbiologi
25	Epigenetic Regulation and Reprogramming of the H19 Imprinting Control Region Mariano, Piero January 2006 (has links) 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
26	Epigenetic Regulation of Genomic Imprinting and Higher Order Chromatin Conformation / Epigenetisk reglering av genetisk prägling och kromatinets konformation Tavoosidana, Gholamreza January 2006 (has links) 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
27	CTCF Contributes to the Regulation of the Ribosomal DNA in Drosophila melanogaster Guerrero, Paola 2011 December 1900 (has links) The 35S rDNA gene clusters on the X and Y chromosomes of Drosophila melanogaster are repeats of approximately 150 to 225 copies. Each are transcribed as a single unit by RNA Polymerase I and modified into the 18S, 5.8S, 2S and 28S ribosomal rRNAs. Reduction in the array copy number results in a bobbed phenotype, characterized by truncated bristles and herniations of abdominal cuticle, due to a decrease in protein production. In some copies within the arrays, R1 and R2 retrotransposable elements are inserted in a conserved region of the 28S gene which represses the transcription of a functional rRNA. Inserted arrays are transcribed at very low levels, but it is not clear how they are identified for repression. Similarly, a subset of uninserted arrays are silenced, and the epigenetic mechanism controlling how this decision is made it is also unknown. The CCCTC binding factor (CTCF) is a boundary element binding protein and a transcriptional regulator found in the nucleolus of differentiated mammalian cells, whose localization requires poly (ADP-ribosyl)ation. We investigated whether CTCF might be involved in the regulation of rDNA expression in Drosophila. Our data show that CTCF is found at the nucleolus of both polytene and diploid nuclei, and we have identified binding sites in the 28S gene, R1 and R2 elements by a bioinformatic approach. ChIP data indicate that CTCF binds only to the site in the R1 retrotransposon. Reduction of CTCF or members of the poly(ADP-ribosyl)ation pathway by RNAi in S2 cells causes an increase in the amount of 35S rDNA gene, R1, and R2 transcripts. In flies, CTCF and PARG mutant alleles show disrupted nucleoli and increased rRNA transcripts. Mutant alleles of CTCF suppress variegation of a P-element inserted in a 35S rDNA array, but not of elements inserted elsewhere in the genome. Consistent with a role for CTCF in rRNA regulation, we found that during oogenesis CTCF is recruited to the nucleolus of nurse cells at early stages when the demand of ribosomes is low and it leaves this compartment in later stages when the cell increases rRNA production. We conclude from these studies that CTCF acts as a regulation of rDNA transcription by RNA polymerase I. CTCF 35S rDNA RNA polymerase I R1 retrotransposons R2 retrotransposons repressor
28	Mechanisms of DNA methylation defects at the IGF2/H19 imprinting centre in patients with foetal growth disorders Shmela, Mansur Ennuri, S3149770@student.rmit.edu.au January 2009 (has links) The imprinted expression of the IGF2 and H19 genes is controlled by the imprinting control region 1 (ICR1) located at chromosome 11p15.5. This methylation-sensitive chromatin insulator works by binding the zinc-finger protein CTCF in a parent-specific manner. CTCF binds the unmethylated maternal allele and is required for preventing de novo methylation at ICR1. DNA methylation defects involving the ICR1 IGF2/H19 domain result in two growth disorders with opposite phenotypes: an overgrowth disorder, the Beckwith-Wiedemann syndrome (ICR1 gain of methylation in 10% of BWS cases) and a growth retardation disorder, the Silver-Russell syndrome (ICR1 loss of methylation in 60% of SRS cases). Little information is available regarding the mechanism of ICR1 DNA methylation defects. Several deletions removing part of ICR1 (1.4 to 2.2 kb) have been described in a few familial BWS cases with dominant maternal transmission. In order to evaluate precisely the incidence of ICR1 mutations, we investigated, by long range PCR and sequencing, 21 BWS patients (including two brothers) with ICR1 gain of methylation and 16 SRS patients with ICR1 loss of methylation. No mutation of the seven CTCF binding sites was detected in the familial BWS cases. Two additional cases of constitutional genetic lesions were identified in BWS patients with apparently-sporadic forms. One patient was identified with a 8 bp deletion within the B3 repeat, 116 bases 3' of the CTCF binding site 4. Another patient was identified with a 1.8 kb deletion which eliminates CTCF binding sites 2 and 3. A single-nucleotide variation was identified in a SRS patient. Our data showed that ICR1 deletions, including new small deletions, account for apparently sporadic forms of BWS with ICR1 gain of methylation. ICR1 deletions are associated with a high incidence of Wilms' tumour, making their molecular diagnosis particularly important for genetic counseling and tumor surveillance. IGF2 gene Foetal Growth ICR1 CTCF binding sites imprinting 11p15 region.
29	Dissecting the molecular mechanism and spatiotemporal dynamics controlling senescence entry Sofiadis, Konstantinos 10 February 2020 (has links) No description available. 570 HMGB1 HMGB2 senescence genome structure TADs CTCF foci transcription Biologie (PPN619462639)
30	Role of miR-122 in Acetaminophen Induced Liver Injury. Chowdhary, Vivek K. 23 October 2017 (has links) No description available. Biomedical Research Molecular Biology

Search results