HnRNPK maintains single strand RNA through controlling double-strand RNA in mammalian cells

Although antisense transcription is a widespread event in the mammalian genome, double-stranded RNA (dsRNA) formation between sense and antisense transcripts is very rare and mechanisms that control dsRNA remain unknown. By characterizing the FGF-2 regulated transcriptome in normal and cancer cells, we identified sense and antisense transcripts IER3 and IER3-AS1 that play a critical role in FGF-2 controlled oncogenic pathways. We show that IER3 and IER3-AS1 regulate each other\u27s transcription through HnRNPK-mediated post-transcriptional regulation. HnRNPK controls the mRNA stability and colocalization of IER3 and IER3-AS1. HnRNPK interaction with IER3 and IER3-AS1 determines their oncogenic functions by maintaining them in a single-stranded form. hnRNPK depletion neutralizes their oncogenic functions through promoting dsRNA formation and cytoplasmic accumulation. Intriguingly, hnRNPK loss-of-function and gain-of-function experiments reveal its role in maintaining global single- and double-stranded RNA. Thus, our data unveil the critical role of HnRNPK in maintaining single-stranded RNAs and their physiological functions by blocking RNA-RNA interactions

The Functional Significance and Chromatin Organisation of the Imprinting Control Regions of the H19 and Kcnq1 Genes

Genomic imprinting is a phenomenon through which a subset of genes are epigenetically marked during gemtogenisis. This mark is maintained in the soma to often manifest parent of origin-specific monoalleleic expresson patterns. Genetics evidence suggests that gene expression patterns in mprinted genes, which are frequently organised in clusters, are regulated by the imprinting control regions (ICR). This thesis is mainly focused on the mechanisms through which the ICRs control the imprinting in the cluster, containing the Kcnq1, Igf2 and H19 genes, located at the distal end of mouse chromosome 7. The H19 ICR, located in the 5' flank of the H19 gene represses paternal H19 and maternal Igf2 expression, respectively, but has no effect on Kcnq1 expression, which is controlled by another ICR located at the intron 10 of the Kcnq1 gene. This thesis demonstrates that the maternal H19 ICR allele contains several DNase I hypersensitive sites, which map to target sites for the chromatin insulator protein CTCF at the linker regions between the positioned nucleosomes. The thesis demonstrates that the H19 ICR acts as a unidirectional insulator and that this property invovles three nucleosome positioning sites facilitating interaction between the H19 ICR and CTCF. The Kcnq1 ICR function is much more complex, since it horbours both lineage-specific silencing functions and a methylation sensitive unidirectional chromatin insulator function. Importantly, the thesis demonstrates that the Kcnq1 ICR spreads DNA methylation into flanking region only when it is itself unmethylated. Both the methylation spreading and silencing functions map to the same regions. In conclusion, the thesis has unraveled and unrivalled complexity of the epigenetic control and function of short strtches of sequences. The epigenetic status of these cis elements conspires to control long-range silencing and insulation. The manner these imprinting control regions can cause havoc in expresson domains in human diseases is hence emerging

The Functional Significance and Chromatin Organisation of the Imprinting Control Regions of the H19 and Kcnq1 Genes

Genomic imprinting is a phenomenon through which a subset of genes are epigenetically marked during gemtogenisis. This mark is maintained in the soma to often manifest parent of origin-specific monoalleleic expresson patterns. Genetics evidence suggests that gene expression patterns in mprinted genes, which are frequently organised in clusters, are regulated by the imprinting control regions (ICR). This thesis is mainly focused on the mechanisms through which the ICRs control the imprinting in the cluster, containing the Kcnq1, Igf2 and H19 genes, located at the distal end of mouse chromosome 7. The H19 ICR, located in the 5' flank of the H19 gene represses paternal H19 and maternal Igf2 expression, respectively, but has no effect on Kcnq1 expression, which is controlled by another ICR located at the intron 10 of the Kcnq1 gene. This thesis demonstrates that the maternal H19 ICR allele contains several DNase I hypersensitive sites, which map to target sites for the chromatin insulator protein CTCF at the linker regions between the positioned nucleosomes. The thesis demonstrates that the H19 ICR acts as a unidirectional insulator and that this property invovles three nucleosome positioning sites facilitating interaction between the H19 ICR and CTCF. The Kcnq1 ICR function is much more complex, since it horbours both lineage-specific silencing functions and a methylation sensitive unidirectional chromatin insulator function. Importantly, the thesis demonstrates that the Kcnq1 ICR spreads DNA methylation into flanking region only when it is itself unmethylated. Both the methylation spreading and silencing functions map to the same regions. In conclusion, the thesis has unraveled and unrivalled complexity of the epigenetic control and function of short strtches of sequences. The epigenetic status of these cis elements conspires to control long-range silencing and insulation. The manner these imprinting control regions can cause havoc in expresson domains in human diseases is hence emerging

CpG methylation regulates the Igf2/H19 insulator

AbstractThe differentially methylated 5′-flank of the mouse H19 gene unidirectionally regulates the communication between enhancer elements and gene promoters and presumably represses maternal Igf2 expression in vivo [1–6]. The specific activation of the paternally inherited Igf2 allele has been proposed to involve methylation-mediated inactivation of the H19 insulator function during male germline development [1–4, 6]. Here, we addressed the role of methylation by inserting a methylated fragment of the H19-imprinting control region (ICR) into a nonmethylated episomal H19 minigene construct, followed by the transfection of ligation mixture into Hep3B cells. Individual clones were expanded and analyzed for genotype, methylation status, chromatin conformation, and insulator function. The results show that the methylated status of the H19 ICR could be propagated for several passages without spreading into the episomal vector. Moreover, the nuclease hypersensitive sites, which are typical for the maternally inherited H19 ICR allele [1], were absent on the methylated ICR, underscoring the suggestion that the methylation mark dictates parent of origin-specific chromatin conformations [1] that involve CTCF [2]. Finally, the insulator function was strongly attenuated in stably maintained episomes. Collectively, these results provide the first experimental support that the H19 insulator function is regulated by CpG methylation

Additional file 6: of Global DNA methylation profiling reveals new insights into epigenetically deregulated protein coding and long noncoding RNAs in CLL

Additonal data 5. (XLS 5827 kb

Additional file 3: of Global DNA methylation profiling reveals new insights into epigenetically deregulated protein coding and long noncoding RNAs in CLL

Additonal data 2. (XLS 172 kb

Global distribution of DNA hydroxymethylation and DNA methylation in chronic lymphocytic leukemia

Abstract Background Chronic lymphocytic leukemia (CLL) has been a good model system to understand the functional role of 5-methylcytosine (5-mC) in cancer progression. More recently, an oxidized form of 5-mC, 5-hydroxymethylcytosine (5-hmC) has gained lot of attention as a regulatory epigenetic modification with prognostic and diagnostic implications for several cancers. However, there is no global study exploring the role of 5-hydroxymethylcytosine (5-hmC) levels in CLL. Herein, using mass spectrometry and hMeDIP-sequencing, we analysed the dynamics of 5-hmC during B cell maturation and CLL pathogenesis. Results We show that naïve B-cells had higher levels of 5-hmC and 5-mC compared to non-class switched and class-switched memory B-cells. We found a significant decrease in global 5-mC levels in CLL patients (n = 15) compared to naïve and memory B cells, with no changes detected between the CLL prognostic groups. On the other hand, global 5-hmC levels of CLL patients were similar to memory B cells and reduced compared to naïve B cells. Interestingly, 5-hmC levels were increased at regulatory regions such as gene-body, CpG island shores and shelves and 5-hmC distribution over the gene-body positively correlated with degree of transcriptional activity. Importantly, CLL samples showed aberrant 5-hmC and 5-mC pattern over gene-body compared to well-defined patterns in normal B-cells. Integrated analysis of 5-hmC and RNA-sequencing from CLL datasets identified three novel oncogenic drivers that could have potential roles in CLL development and progression. Conclusions Thus, our study suggests that the global loss of 5-hmC, accompanied by its significant increase at the gene regulatory regions, constitute a novel hallmark of CLL pathogenesis. Our combined analysis of 5-mC and 5-hmC sequencing provided insights into the potential role of 5-hmC in modulating gene expression changes during CLL pathogenesis

An Antisense RNA Regulates the Bidirectional Silencing Property of the Kcnq1 Imprinting Control Region

The Kcnq1 imprinting control region (ICR) located in intron 10 of the Kcnq1 gene is unmethylated on the paternal chromosome and methylated on the maternal chromosome and has been implicated in the manifestation of parent-of-origin-specific expression of six neighboring genes. The unmethylated Kcnq1 ICR harbors bidirectional silencer activity and drives expression of an antisense RNA, Kcnq1ot1, which overlaps the Kcnq1 coding region. To elucidate whether the Kcnq1ot1 RNA plays a role in the bidirectional silencing activity of the Kcnq1 ICR, we have characterized factor binding sites by genomic footprinting and tested the functional consequence of various deletions of these binding sites in an episome-based system. Deletion of the elements necessary for Kcnq1ot1 promoter function resulted in the loss of silencing activity. Furthermore, interruption of Kcnq1ot1 RNA production by the insertion of a polyadenylation sequence downstream of the promoter also caused a loss of both silencing activity and methylation spreading. Thus, the antisense RNA plays a key role in the silencing function of the ICR. Double-stranded RNA (dsRNA)-mediated RNA interference is unlikely to be involved, as the ICR is active irrespective of the simultaneous production of dsRNA from the genes it silences