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40 results on '"Pradeepa, Madapura M."'

2. Nucleosome reorganisation in breast cancer tissues

Author

Jacob, Divya R., Guiblet, Wilfried M., Mamayusupova, Hulkar, Shtumpf, Mariya, Ciuta, Isabella, Ruje, Luminita, Gretton, Svetlana, Bikova, Milena, Correa, Clark, Dellow, Emily, Agrawal, Shivam P., Shafiei, Navid, Drobysevskaja, Anastasija, Armstrong, Chris M., Lam, Jonathan D. G., Vainshtein, Yevhen, Clarkson, Christopher T., Thorn, Graeme J., Sohn, Kai, Pradeepa, Madapura M., Chandrasekharan, Sankaran, Brooke, Greg N., Klenova, Elena, Zhurkin, Victor B., and Teif, Vladimir B.

Published
2024
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9. Nucleosome reorganisation in breast cancer tissues

Author

Jacob, Divya R., primary, Guiblet, Wilfried M., additional, Mamayusupova, Hulkar, additional, Shtumpf, Mariya, additional, Ruje, Luminita, additional, Ciuta, Isabella, additional, Gretton, Svetlana, additional, Correa, Clark, additional, Dellow, Emily, additional, Agrawal, Shivam P., additional, Shafiei, Navid, additional, Drobysevskaja, Anastasija, additional, Armstrong, Chris M., additional, Lam, Jonathan D. G., additional, Vainshtein, Yevhen, additional, Clarkson, Christopher T., additional, Thorn, Graeme J., additional, Sohn, Kai, additional, Pradeepa, Madapura M., additional, Chandrasekharan, Sankaran, additional, Brooke, Greg N., additional, Klenova, Elena, additional, Zhurkin, Victor B., additional, and Teif, Vladimir B., additional

Published
2023
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10. Regulatory de novo mutations underlying intellectual disability

Author

Vas, Matías G. de, Boulet, Fanny, Joshi, Shweta S., Garstang, Myles G., Khan, Tahir N., Atla, Goutham, Parry, David, Moore, David, Cebola, Inês, Zhang, Shuchen, Cui, Wei, 1970, Lampe, Anne K., Lam, Wayne W., Genomics England Research Consortium, Ferrer, Jorge, Pradeepa, Madapura M., Atanur, Santosh S., Wellcome Trust, Medical Research Council (MRC), Imperial College Healthcare NHS Trust- BRC Funding, and Imperial College Healthcare NHS Trust

Subjects
Adult, Mutation/genetics, Ecology, Health, Toxicology and Mutagenesis, Plant Science, Biochemistry, Genetics and Molecular Biology (miscellaneous), Intellectual Disability/genetics, Genomics England Research Consortium, Intellectual Disability, Genes, Regulator, Mutation, Humans, Biological Assay, Alleles
Abstract

The genetic aetiology of a major fraction of patients with intellectual disability (ID) remains unknown. De novo mutations (DNMs) in protein-coding genes explain up to 40% of cases, but the potential role of regulatory DNMs is still poorly understood. We sequenced 63 whole genomes from 21 ID probands and their unaffected parents. In addition, we analysed 30 previously sequenced genomes from exome-negative ID probands. We found that regulatory DNMs were selectively enriched in fetal brain-specific enhancers as compared with adult brain enhancers. DNM-containing enhancers were associated with genes that show preferential expression in the prefrontal cortex. Furthermore, we identified recurrently mutated enhancer clusters that regulate genes involved in nervous system development (CSMD1, OLFM1, and POU3F3). Most of the DNMs from ID probands showed allele-specific enhancer activity when tested using luciferase assay. Using CRISPR-mediated mutation and editing of epigenomic marks, we show that DNMs at regulatory elements affect the expression of putative target genes. Our results, therefore, provide new evidence to indicate that DNMs in fetal brain-specific enhancers play an essential role in the aetiology of ID. This work was funded by grants from the Wellcome Trust Institute Strategic Support and National Institute for Health Research (NIHR) Imperial Biomedical Research Centre, Institute for Translational Medicine and Therapeutics (P70888) obtained by SS Atanur. J Ferrer and MG De Vas’s work was funded by grants from the Wellcome Trust (WT101033 to J Ferrer), Medical Research Council (MR/L02036X/1 to J Ferrer), and European Research Council Advanced Grant (789055 to J Ferrer). MM Pradeepa’s lab is funded by the UKRI/MRC (MR/T000783/1), and Barts charity (MGU0475) grants. TN Khan was partially supported by the Government of Pakistan under the PSDP project “Development of National University of Medical Sciences (NUMS), Rawalpindi.”

Published
2023

11. Genetic variation at mouse and human ribosomal DNA influences associated epigenetic states

Author

Rodriguez‑Algarra, Francisco, Seaborne, Robert A. E., Danson, Amy F., Yildizoglu, Selin, Yoshikawa, Harunori, Law, Pui Pik, Ahmad, Zakaryya, Maudsley, Victoria A., Brew, Ama, Holmes, Nadine, Ochôa, Mateus, Hodgkinson, Alan, Marzi, Sarah J., Pradeepa, Madapura M., Loose, Matthew, Holland, Michelle L., Rakyan, Vardhman K., Rodriguez‑Algarra, Francisco, Seaborne, Robert A. E., Danson, Amy F., Yildizoglu, Selin, Yoshikawa, Harunori, Law, Pui Pik, Ahmad, Zakaryya, Maudsley, Victoria A., Brew, Ama, Holmes, Nadine, Ochôa, Mateus, Hodgkinson, Alan, Marzi, Sarah J., Pradeepa, Madapura M., Loose, Matthew, Holland, Michelle L., and Rakyan, Vardhman K.

Abstract

Background: Ribosomal DNA (rDNA) displays substantial inter-individual genetic variation in human and mouse. A systematic analysis of how this variation impacts epigenetic states and expression of the rDNA has thus far not been performed. Results: Using a combination of long- and short-read sequencing, we establish that 45S rDNA units in the C57BL/6J mouse strain exist as distinct genetic haplotypes that influence the epigenetic state and transcriptional output of any given unit. DNA methylation dynamics at these haplotypes are dichotomous and life-stage specific: at one haplotype, the DNA methylation state is sensitive to the in utero environment, but refractory to post-weaning influences, whereas other haplotypes entropically gain DNA methylation during aging only. On the other hand, individual rDNA units in human show limited evidence of genetic haplotypes, and hence little discernible correlation between genetic and epigenetic states. However, in both species, adjacent units show similar epigenetic profiles, and the overall epigenetic state at rDNA is strongly positively correlated with the total rDNA copy number. Analysis of different mouse inbred strains reveals that in some strains, such as 129S1/SvImJ, the rDNA copy number is only approximately 150 copies per diploid genome and DNA methylation levels are < 5%. Conclusions: Our work demonstrates that rDNA-associated genetic variation has a considerable influence on rDNA epigenetic state and consequently rRNA expression outcomes. In the future, it will be important to consider the impact of inter-individual rDNA (epi)genetic variation on mammalian phenotypes and diseases.

Published
2022

15. Additional file 1 of Genetic variation at mouse and human ribosomal DNA influences associated epigenetic states

Author

Rodriguez-Algarra, Francisco, Seaborne, Robert A. E., Danson, Amy F., Yildizoglu, Selin, Yoshikawa, Harunori, Law, Pui Pik, Ahmad, Zakaryya, Maudsley, Victoria A., Brew, Ama, Holmes, Nadine, Och��a, Mateus, Hodgkinson, Alan, Marzi, Sarah J., Pradeepa, Madapura M., Loose, Matthew, Holland, Michelle L., and Rakyan, Vardhman K.

Subjects
Data_FILES
Abstract

Additional file 1. Extended data analysis methods.

Published
2022
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16. Additional file 3 of Genetic variation at mouse and human ribosomal DNA influences associated epigenetic states

Author

Rodriguez-Algarra, Francisco, Seaborne, Robert A. E., Danson, Amy F., Yildizoglu, Selin, Yoshikawa, Harunori, Law, Pui Pik, Ahmad, Zakaryya, Maudsley, Victoria A., Brew, Ama, Holmes, Nadine, Och��a, Mateus, Hodgkinson, Alan, Marzi, Sarah J., Pradeepa, Madapura M., Loose, Matthew, Holland, Michelle L., and Rakyan, Vardhman K.

Abstract

Additional file 3. Supplementary figures S1-S20.

Published
2022
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19. Genetic variation at mouse and human ribosomal DNA influences associated epigenetic states

Author

Rodriguez-Algarra, Francisco, primary, Seaborne, Robert A E, additional, Danson, Amy F, additional, Yildizoglu, Selin, additional, Yoshikawa, Harunori, additional, Law, Pui Pik, additional, Ahmad, Zakaryya, additional, Maudsley, Victoria A, additional, Brew, Ama, additional, Holmes, Nadine, additional, Ochôa, Mateus, additional, Hodgkinson, Alan, additional, Marzi, Sarah J, additional, Pradeepa, Madapura M, additional, Loose, Matthew, additional, Holland, Michelle L, additional, and Rakyan, Vardhman K, additional

Published
2021
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22. De novo variants in population constrained fetal brain enhancers and intellectual disability

Author

De Vas, Matias G, primary, Garstang, Myles G, additional, Joshi, Shweta S, additional, Khan, Tahir N, additional, Atla, Goutham, additional, Parry, David, additional, Moore, David, additional, Cebola, Ines, additional, Zhang, Shuchen, additional, Cui, Wei, additional, Lampe, Anne K, additional, Lam, Wayne W, additional, FitzPatrick, David R, additional, Ferrer, Jorge, additional, Pradeepa, Madapura M, additional, and Atanur, Santosh S, additional

Published
2019
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23. Psip1/p52 regulates posterior Hoxa genes through activation of lncRNA Hottip

Author

Pradeepa, Madapura M., McKenna, Fionnuala, Taylor, Gillian C. A., Bengani, Hemant, Grimes, Graeme R., Wood, Andrew J., Bhatia, Shipra, and Bickmore, Wendy A.

Subjects
lcsh:Genetics, lcsh:QH426-470
Abstract

Long noncoding RNAs (lncRNAs) have been implicated in various biological functions including the regulation of gene expression, however, the functionality of lncRNAs is not clearly understood and conflicting conclusions have often been reached when comparing different methods to investigate them. Moreover, little is known about the upstream regulation of lncRNAs. Here we show that the short isoform (p52) of a transcriptional co-activator—PC4 and SF2 interacting protein (Psip1), which is known to be involved in linking transcription to RNA processing, specifically regulates the expression of the lncRNA Hottip–located at the 5’ end of the Hoxa locus. Using both knockdown and knockout approaches we show that Hottip expression is required for activation of the 5’ Hoxa genes (Hoxa13 and Hoxa10/11) and for retaining Mll1 at the 5’ end of Hoxa. Moreover, we demonstrate that artificially inducing Hottip expression is sufficient to activate the 5’ Hoxa genes and that Hottip RNA binds to the 5’ end of Hoxa. By engineering premature transcription termination, we show that it is the Hottip lncRNA molecule itself, not just Hottip transcription that is required to maintains active expression of posterior Hox genes. Our data show a direct role for a lncRNA molecule in regulating the expression of developmentally-regulated mRNA genes in cis.

Published
2017

24. Convergent origination of a Drosophila-like dosage compensation mechanism in a reptile lineage

Author

Marin, Ray, primary, Cortez, Diego, additional, Lamanna, Francesco, additional, Pradeepa, Madapura M., additional, Leushkin, Evgeny, additional, Julien, Philippe, additional, Liechti, Angélica, additional, Halbert, Jean, additional, Brüning, Thoomke, additional, Mössinger, Katharina, additional, Trefzer, Timo, additional, Conrad, Christian, additional, Kerver, Halie N., additional, Wade, Juli, additional, Tschopp, Patrick, additional, and Kaessmann, Henrik, additional

Published
2017
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29. An Interferon Regulated MicroRNA Provides Broad Cell-Intrinsic Antiviral Immunity through Multihit Host-Directed Targeting of the Sterol Pathway

Author

Robertson, Kevin A., primary, Hsieh, Wei Yuan, additional, Forster, Thorsten, additional, Blanc, Mathieu, additional, Lu, Hongjin, additional, Crick, Peter J., additional, Yutuc, Eylan, additional, Watterson, Steven, additional, Martin, Kimberly, additional, Griffiths, Samantha J., additional, Enright, Anton J., additional, Yamamoto, Mami, additional, Pradeepa, Madapura M., additional, Lennox, Kimberly A., additional, Behlke, Mark A., additional, Talbot, Simon, additional, Haas, Jürgen, additional, Dölken, Lars, additional, Griffiths, William J., additional, Wang, Yuqin, additional, Angulo, Ana, additional, and Ghazal, Peter, additional

Published
2016
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31. Acetylation of Transition Protein 2 (TP2) by KAT3B (p300) Alters Its DNA Condensation Property and Interaction with Putative Histone Chaperone NPM3

Author

Pradeepa, Madapura M, Nikhil, Gupta, Kishore, Annavarapu Hari, Bharath, Giriyapura N, Kundu, Tapas K, and Rao, Manchanahalli R Satyanarayana

Subjects
Biochemistry
Abstract

The hallmark of mammalian spermiogenesis is the dramatic chromatin remodeling process wherein the nucleosomal histones are replaced by the transition proteins TP1, TP2, and TP4. Subsequently these transition proteins are replaced by the protamines P1 and P2. Hyperacetylation of histone H4 is linked to their replacement by transition proteins. Here we report that TP2 is acetylated in vivo as detected by anti-acetylated lysine antibody and mass spectrometric analysis. Further, recombinant TP2 is acetylated in vitro by acetyltransferase KAT3B (p300) more efficiently than by KAT2B (PCAF). In vivo p300 was demonstrated to acetylate TP2. p300 acetylates TP2 in its C-terminal domain, which is highly basic in nature and possesses chromatin-condensing properties. Mass spectrometric analysis showed that p300 acetylates four lysine residues in the C-terminal domain of TP2. Acetylation of TP2 by p300 leads to significant reduction in its DNA condensation property as studied by circular dichroism and atomic force microscopy analysis. TP2 also interacts with a putative histone chaperone, NPM3, wherein expression is elevated in haploid spermatids.Interestingly, acetylation of TP2 impedes its interaction with NPM3. Thus, acetylation of TP2 adds a new dimension to its role in the dynamic reorganization of chromatin during mammalian spermiogenesis.

Published
2009

32. Causal role of histone acetylations in enhancer function.

Author

Pradeepa, Madapura M.

Subjects
*HISTONE acetylation, *GENE enhancers, *GENETIC regulation, *CELL physiology, *MOLECULAR structure of chromatin
Abstract

Enhancers control development and cellular function by spatiotemporal regulation of gene expression. Co-occurrence of acetylation of histone H3 at lysine 27 (H3K27ac) and mono methylation of histone H3 at lysine 4 (H3K4me1) has been widely used for identification of active enhancers. However, increasing evidence suggests that using this combination of marks alone for enhancer identification gives an incomplete picture of the active enhancer repertoire. We have shown that the H3 globular domain acetylations, H3K64ac and H3K122ac, and an H4 tail acetylation, H4K16ac, are enriched at active enhancers together with H3K27ac, and also at a large number of enhancers without detectable H3K27ac. We propose that acetylations at these lysine residues of histones H3 and H4 might function by directly affecting chromatin structure, nucleosome–nucleosome interactions, nucleosome stability, and transcription factor accessibility. [ABSTRACT FROM AUTHOR]

Published
2017
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38. An Interferon Regulated MicroRNA Provides Broad Cell-Intrinsic Antiviral Immunity through Multihit Host-Directed Targeting of the Sterol Pathway

Author

Robertson, Kevin A, Hsieh, Wei Yuan, Forster, Thorsten, Blanc, Mathieu, Lu, Hongjin, Crick, Peter J, Yutuc, Eylan, Watterson, Steven, Martin, Kimberly, Griffiths, Samantha J, Enright, Anton J, Yamamoto, Mami, Pradeepa, Madapura M, Lennox, Kimberly A, Behlke, Mark A, Talbot, Simon, Haas, Jürgen, Dölken, Lars, Griffiths, William J, Wang, Yuqin, Angulo, Ana, and Ghazal, Peter

Subjects
Mice, Inbred C57BL, MicroRNAs, Sterols, Virus Diseases, Animals, Interferons, 3. Good health, Interferon Regulatory Factor-1
Abstract

In invertebrates, small interfering RNAs are at the vanguard of cell-autonomous antiviral immunity. In contrast, antiviral mechanisms initiated by interferon (IFN) signaling predominate in mammals. Whilst mammalian IFN-induced miRNA are known to inhibit specific viruses, it is not known whether host-directed microRNAs, downstream of IFN-signaling, have a role in mediating broad antiviral resistance. By performing an integrative, systematic, global analysis of RNA turnover utilizing 4-thiouridine labeling of newly transcribed RNA and pri/pre-miRNA in IFN-activated macrophages, we identify a new post-transcriptional viral defense mechanism mediated by miR-342-5p. On the basis of ChIP and site-directed promoter mutagenesis experiments, we find the synthesis of miR-342-5p is coupled to the antiviral IFN response via the IFN-induced transcription factor, IRF1. Strikingly, we find miR-342-5p targets mevalonate-sterol biosynthesis using a multihit mechanism suppressing the pathway at different functional levels: transcriptionally via SREBF2, post-transcriptionally via miR-33, and enzymatically via IDI1 and SC4MOL. Mass spectrometry-based lipidomics and enzymatic assays demonstrate the targeting mechanisms reduce intermediate sterol pathway metabolites and total cholesterol in macrophages. These results reveal a previously unrecognized mechanism by which IFN regulates the sterol pathway. The sterol pathway is known to be an integral part of the macrophage IFN antiviral response, and we show that miR-342-5p exerts broad antiviral effects against multiple, unrelated pathogenic viruses such Cytomegalovirus and Influenza A (H1N1). Metabolic rescue experiments confirm the specificity of these effects and demonstrate that unrelated viruses have differential mevalonate and sterol pathway requirements for their replication. This study, therefore, advances the general concept of broad antiviral defense through multihit targeting of a single host pathway.

39. H4K16ac activates the transcription of transposable elements and contributes to their cis-regulatory function

Author

Debosree Pal, Manthan Patel, Fanny Boulet, Jayakumar Sundarraj, Olivia A Grant, Miguel R. Branco, Srinjan Basu, Silvia Santos, Nicolae Radu Zabet, Paola Scaffidi, Madapura M Pradeepa, Branco, Miguel R [0000-0001-9447-1548], Basu, Srinjan [0000-0002-1080-979X], Santos, Silvia DM [0000-0002-2906-7888], Scaffidi, Paola [0000-0002-3642-4193], Pradeepa, Madapura M [0000-0001-9095-9247], and Apollo - University of Cambridge Repository

Subjects
1.1 Normal biological development and functioning, Human Genome, Genetics, 1 Underpinning research, 32 Biomedical and Clinical Sciences, Generic health relevance, Stem Cell Research, 3105 Genetics, 31 Biological Sciences, Cancer
Abstract

Mammalian genomes harbour a large number of transposable elements (TEs) and their remnants. Many epigenetic repression mechanisms are known to silence TE transcription. However, TEs are upregulated during early development, neuronal lineage, and cancers, although the epigenetic factors contributing to the transcription of TEs have yet to be fully elucidated. Here we demonstrated that the male-specific lethal (MSL) complex mediated acetylation of histone H4 lysine 16 (H4K16ac) activates transcription of long interspersed nuclear elements (LINE1, L1) and long terminal repeats (LTRs). Furthermore, we show that the H4K16ac marked L1 and LTR subfamilies function as enhancers and are enriched with chromatin features associated with active enhancers and looping factors. L1 and LTRs enriched with histone acetylations are bound by chromatin looping factors and these regions loop with genes. CRISPR-based epigenetic perturbation and genetic deletion of L1s reveal that H4K16ac marked L1s and LTRs regulate the expression of genes in cis. Overall, TEs enriched with H4K16ac contribute to the cis-regulatory landscape of a significant portion of the mammalian genome by maintaining an active chromatin landscape at TEs.One Sentence SummaryH4K16ac activates LINE1 and ERV/LTR transcription and rewires the cis-regulatory landscape of a significant portion of the mammalian genome by increasing the transcriptional activity at TEs.

Published
2023

40. An Enhancer-Derived RNA Muscles In to Regulate Myogenin In trans.

Author

Garstang MG and Pradeepa MMM

Subjects
Cell Cycle Proteins, Chromosomal Proteins, Non-Histone, Enhancer Elements, Genetic, Cohesins, Myogenin, RNA
Abstract

Noncoding RNAs (ncRNAs) transcribed from active enhancers are known as enhancer RNAs (eRNAs). eRNAs have generally been shown to contribute to transcriptional activation of target genes in cis. In this issue, Tsai et al. (2018) demonstrate that an eRNA expressed from a distal enhancer of Myogenic differentiation1 (MyoD) ( DRR eRNA) does not regulate its neighboring MyoD; instead, it promotes myogenic differentiation by activating Myogenin, which is located on a different chromosome., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published
2018
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