Your search keyword '"de Hoon MJL"' showing total 14 results

1. Author Correction: Discovery of widespread transcription initiation at microsatellites predictable by sequence-based deep neural network.

Author

Grapotte, M, Saraswat, M, Bessière, C, Menichelli, C, Ramilowski, JA, Severin, J, Hayashizaki, Y, Itoh, M, Tagami, M, Murata, M, Kojima-Ishiyama, M, Noma, S, Noguchi, S, Kasukawa, T, Hasegawa, A, Suzuki, H, Nishiyori-Sueki, H, Frith, MC, FANTOM consortium, Chatelain, C, Carninci, P, de Hoon, MJL, Wasserman, WW, Bréhélin, L, Lecellier, C-H, Grapotte, M, Saraswat, M, Bessière, C, Menichelli, C, Ramilowski, JA, Severin, J, Hayashizaki, Y, Itoh, M, Tagami, M, Murata, M, Kojima-Ishiyama, M, Noma, S, Noguchi, S, Kasukawa, T, Hasegawa, A, Suzuki, H, Nishiyori-Sueki, H, Frith, MC, FANTOM consortium, Chatelain, C, Carninci, P, de Hoon, MJL, Wasserman, WW, Bréhélin, L, and Lecellier, C-H

Published

2022

2. Functional annotation of human long noncoding RNAs via molecular phenotyping (vol 30, pg 1060, 2020)

Author

Ramilowski, JA, Yip, CW, Agrawal, S, Chang, J-C, Ciani, Y, Kulakovskiy, IV, Mendez, M, Ooi, JLC, Ouyang, JF, Parkinson, N, Petri, A, Roos, L, Severin, J, Yasuzawa, K, Abugessaisa, I, Akalin, A, Antonov, IV, Arner, E, Bonetti, A, Bono, H, Borsari, B, Brombacher, F, Cameron, CJF, Cannistraci, CV, Cardenas, R, Cardon, M, Chang, H, Dostie, J, Ducoli, L, Favorov, A, Fort, A, Garrido, D, Gil, N, Gimenez, J, Guler, R, Handoko, L, Harshbarger, J, Hasegawa, A, Hasegawa, Y, Hashimoto, K, Hayatsu, N, Heutink, P, Hirose, T, Imada, EL, Itoh, M, Kaczkowski, B, Kanhere, A, Kawabata, E, Kawaji, H, Kawashima, T, Kelly, ST, Kojima, M, Kondo, N, Koseki, H, Kouno, T, Kratz, A, Kurowska-Stolarska, M, Kwon, ATJ, Leek, J, Lennartsson, A, Lizio, M, Lopez-Redondo, F, Luginbuhl, J, Maeda, S, Makeev, VJ, Marchionni, L, Medvedeva, YA, Minoda, A, Muller, F, Munoz-Aguirre, M, Murata, M, Nishiyori, H, Nitta, KR, Noguchi, S, Noro, Y, Nurtdinov, R, Okazaki, Y, Orlando, V, Paquette, D, Parr, CJC, Rackham, OJL, Rizzu, P, Martinez, DFS, Sandelin, A, Sanjana, P, Semple, CAM, Shibayama, Y, Sivaraman, DM, Suzuki, T, Szumowski, SC, Tagami, M, Taylor, MS, Terao, C, Thodberg, M, Thongjuea, S, Tripathi, V, Ulitsky, I, Verardo, R, Vorontsov, IE, Yamamoto, C, Young, RS, Baillie, JK, Forrest, ARR, Guigo, R, Hoffman, MM, Hon, CC, Kasukawa, T, Kauppinen, S, Kere, J, Lenhard, B, Schneider, C, Suzuki, H, Yagi, K, De Hoon, MJL, Shin, JW, Carninci, P, and Wellcome Trust

Subjects

Genetics & Heredity, Biochemistry & Molecular Biology, Science & Technology, Biotechnology & Applied Microbiology, Bioinformatics, 06 Biological Sciences, Life Sciences & Biomedicine, 11 Medical and Health Sciences

Published

2020

3. Discovery of widespread transcription initiation at microsatellites predictable by sequence-based deep neural network.

Author

Grapotte, M, Saraswat, M, Bessière, C, Menichelli, C, Ramilowski, JA, Severin, J, Hayashizaki, Y, Itoh, M, Tagami, M, Murata, M, Kojima-Ishiyama, M, Noma, S, Noguchi, S, Kasukawa, T, Hasegawa, A, Suzuki, H, Nishiyori-Sueki, H, Frith, MC, FANTOM consortium, Chatelain, C, Carninci, P, de Hoon, MJL, Wasserman, WW, Bréhélin, L, Lecellier, C-H, Grapotte, M, Saraswat, M, Bessière, C, Menichelli, C, Ramilowski, JA, Severin, J, Hayashizaki, Y, Itoh, M, Tagami, M, Murata, M, Kojima-Ishiyama, M, Noma, S, Noguchi, S, Kasukawa, T, Hasegawa, A, Suzuki, H, Nishiyori-Sueki, H, Frith, MC, FANTOM consortium, Chatelain, C, Carninci, P, de Hoon, MJL, Wasserman, WW, Bréhélin, L, and Lecellier, C-H

Abstract

Using the Cap Analysis of Gene Expression (CAGE) technology, the FANTOM5 consortium provided one of the most comprehensive maps of transcription start sites (TSSs) in several species. Strikingly, ~72% of them could not be assigned to a specific gene and initiate at unconventional regions, outside promoters or enhancers. Here, we probe these unassigned TSSs and show that, in all species studied, a significant fraction of CAGE peaks initiate at microsatellites, also called short tandem repeats (STRs). To confirm this transcription, we develop Cap Trap RNA-seq, a technology which combines cap trapping and long read MinION sequencing. We train sequence-based deep learning models able to predict CAGE signal at STRs with high accuracy. These models unveil the importance of STR surrounding sequences not only to distinguish STR classes, but also to predict the level of transcription initiation. Importantly, genetic variants linked to human diseases are preferentially found at STRs with high transcription initiation level, supporting the biological and clinical relevance of transcription initiation at STRs. Together, our results extend the repertoire of non-coding transcription associated with DNA tandem repeats and complexify STR polymorphism.

Published

2021

4. The Constrained Maximal Expression Level Owing to Haploidy Shapes Gene Content on the Mammalian X Chromosome

Author

Hurst, LD, Ghanbarian, AT, Forrest, ARR, Huminiecki, L, Rehli, M, Kenneth Baillie, J, de Hoon, MJL, Haberle, V, Lassmann, T, Kulakovskiy, IV, Lizio, M, Itoh, M, Andersson, R, Mungall, CJ, Meehan, TF, Schmeier, S, Bertin, N, Jørgensen, M, Dimont, E, Arner, E, Schmidl, C, Schaefer, U, Medvedeva, YA, Plessy, C, Vitezic, M, Severin, J, Semple, CA, Ishizu, Y, Young, RS, Francescatto, M, Alam, I, Albanese, D, Altschuler, GM, Arakawa, T, Archer, JAC, Arner, P, Babina, M, Baker, S, Balwierz, PJ, Beckhouse, AG, Pradhan, SB, Blake, JA, Blumenthal, A, Bodega, B, Bonetti, A, Briggs, J, Brombacher, F, Maxwell Burroughs, A, Califano, A, Cannistraci, CV, Carbajo, D, Chen, Y, Chierici, M, Ciani, Y, Clevers, HC, Dalla, E, Davis, CA, Detmar, M, Diehl, AD, Dohi, T, Drabløs, F, Edge, ASB, Edinger, M, Ekwall, K, Endoh, M, Enomoto, H, Fagiolini, M, Fairbairn, L, and Fang, H

Abstract

© 2015 Hurst et al. X chromosomes are unusual in many regards, not least of which is their nonrandom gene content. The causes of this bias are commonly discussed in the context of sexual antagonism and the avoidance of activity in the male germline. Here, we examine the notion that, at least in some taxa, functionally biased gene content may more profoundly be shaped by limits imposed on gene expression owing to haploid expression of the X chromosome. Notably, if the X, as in primates, is transcribed at rates comparable to the ancestral rate (per promoter) prior to the X chromosome formation, then the X is not a tolerable environment for genes with very high maximal net levels of expression, owing to transcriptional traffic jams. We test this hypothesis using The Encyclopedia of DNA Elements (ENCODE) and data from the Functional Annotation of the Mammalian Genome (FANTOM5) project. As predicted, the maximal expression of human X-linked genes is much lower than that of genes on autosomes: on average, maximal expression is three times lower on the X chromosome than on autosomes. Similarly, autosome-to-X retroposition events are associated with lower maximal expression of retrogenes on the X than seen for X-to-autosome retrogenes on autosomes. Also as expected, X-linked genes have a lesser degree of increase in gene expression than autosomal ones (compared to the human/Chimpanzee common ancestor) if highly expressed, but not if lowly expressed. The traffic jam model also explains the known lower breadth of expression for genes on the X (and the Z of birds), as genes with broad expression are, on average, those with high maximal expression. As then further predicted, highly expressed tissue-specific genes are also rare on the X and broadly expressed genes on the X tend to be lowly expressed, both indicating that the trend is shaped by the maximal expression level not the breadth of expression per se. Importantly, a limit to the maximal expression level explains biased tissue of expression profiles of X-linked genes. Tissues whose tissue-specific genes are very highly expressed (e.g., secretory tissues, tissues abundant in structural proteins) are also tissues in which gene expression is relatively rare on the X chromosome. These trends cannot be fully accounted for in terms of alternative models of biased expression. In conclusion, the notion that it is hard for genes on the Therian X to be highly expressed, owing to transcriptional traffic jams, provides a simple yet robustly supported rationale of many peculiar features of X’s gene content, gene expression, and evolution.

Published

2015

5. Update of the FANTOM web resource: enhancement for studying noncoding genomes.

Author

Nobusada T, Yip CW, Agrawal S, Severin J, Abugessaisa I, Hasegawa A, Hon CC, Ide S, Koido M, Kondo A, Masuya H, Oki S, Tagami M, Takada T, Terao C, Thalhath N, Walker S, Yasuzawa K, Shin JW, de Hoon MJL, Carninci P, Kawaji H, and Kasukawa T

Subjects

Humans, Animals, Genome genetics, Databases, Genetic, Regulatory Elements, Transcriptional, Genomics methods, Induced Pluripotent Stem Cells metabolism, Software, Molecular Sequence Annotation, Internet, RNA, Long Noncoding genetics, RNA, Long Noncoding metabolism

Abstract

The FANTOM web resource (https://fantom.gsc.riken.jp/) has been a unique resource for studying mammalian genomes, which is built on the research activities conducted in the international collaborative project FANTOM (Functional ANnoTation Of the Mammalian genome). In recent updates, we expanded annotations for long non-coding RNAs (lncRNAs) and transcribed cis-regulatory elements (CREs). The former was derived from the large-scale lncRNA perturbations in induced pluripotent stem cells (iPSCs) and integrative analysis of Hi-C data conducted in the sixth iteration of the project (FANTOM6). The resulting annotations of lncRNAs, according to the impact on cellular and molecular phenotypes and the potential RNA-chromatin interactions, are accessible via the interactive ZENBU-Reports framework. The latter involves a new platform, fanta.bio (https://fanta.bio/), which collects transcribed CREs identified via use of an extended dataset of CAGE profiles. The CREs, with their annotations including genetic and epigenetic information, are accessible via a dedicated interface as well as the UCSC Genome Browser Database. These updates offer enhanced opportunities to investigate the functions of non-coding regions within mammalian genomes., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2025

6. Annotation of nuclear lncRNAs based on chromatin interactions.

Author

Agrawal S, Buyan A, Severin J, Koido M, Alam T, Abugessaisa I, Chang HY, Dostie J, Itoh M, Kere J, Kondo N, Li Y, Makeev VJ, Mendez M, Okazaki Y, Ramilowski JA, Sigorskikh AI, Strug LJ, Yagi K, Yasuzawa K, Yip CW, Hon CC, Hoffman MM, Terao C, Kulakovskiy IV, Kasukawa T, Shin JW, Carninci P, and de Hoon MJL

Subjects

Humans, Molecular Sequence Annotation, Cell Nucleus metabolism, Cell Nucleus genetics, Genome, Human, Promoter Regions, Genetic, RNA, Long Noncoding genetics, RNA, Long Noncoding metabolism, Chromatin metabolism, Chromatin genetics

Abstract

The human genome is pervasively transcribed and produces a wide variety of long non-coding RNAs (lncRNAs), constituting the majority of transcripts across human cell types. Some specific nuclear lncRNAs have been shown to be important regulatory components acting locally. As RNA-chromatin interaction and Hi-C chromatin conformation data showed that chromatin interactions of nuclear lncRNAs are determined by the local chromatin 3D conformation, we used Hi-C data to identify potential target genes of lncRNAs. RNA-protein interaction data suggested that nuclear lncRNAs act as scaffolds to recruit regulatory proteins to target promoters and enhancers. Nuclear lncRNAs may therefore play a role in directing regulatory factors to locations spatially close to the lncRNA gene. We provide the analysis results through an interactive visualization web portal at https://fantom.gsc.riken.jp/zenbu/reports/#F6_3D_lncRNA., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Agrawal et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

7. Author Correction: Discovery of widespread transcription initiation at microsatellites predictable by sequence-based deep neural network.

Author

Grapotte M, Saraswat M, Bessière C, Menichelli C, Ramilowski JA, Severin J, Hayashizaki Y, Itoh M, Tagami M, Murata M, Kojima-Ishiyama M, Noma S, Noguchi S, Kasukawa T, Hasegawa A, Suzuki H, Nishiyori-Sueki H, Frith MC, Chatelain C, Carninci P, de Hoon MJL, Wasserman WW, Bréhélin L, and Lecellier CH

Published

2022

8. The choice of negative control antisense oligonucleotides dramatically impacts downstream analysis depending on the cellular background.

Author

Ducoli L, Agrawal S, Hon CC, Ramilowski JA, Sibler E, Tagami M, Itoh M, Kondo N, Abugessaisa I, Hasegawa A, Kasukawa T, Suzuki H, Carninci P, Shin JW, de Hoon MJL, and Detmar M

Subjects

Adult, Endothelial Cells metabolism, Gene Knockdown Techniques standards, Humans, Lymphatic System cytology, Lymphatic System metabolism, Oligonucleotides, Antisense standards, Transcriptome, Gene Knockdown Techniques methods, Oligonucleotides, Antisense genetics, Organ Specificity genetics, RNA, Long Noncoding genetics

Abstract

Background: The lymphatic and the blood vasculature are closely related systems that collaborate to ensure the organism's physiological function. Despite their common developmental origin, they present distinct functional fates in adulthood that rely on robust lineage-specific regulatory programs. The recent technological boost in sequencing approaches unveiled long noncoding RNAs (lncRNAs) as prominent regulatory players of various gene expression levels in a cell-type-specific manner., Results: To investigate the potential roles of lncRNAs in vascular biology, we performed antisense oligonucleotide (ASO) knockdowns of lncRNA candidates specifically expressed either in human lymphatic or blood vascular endothelial cells (LECs or BECs) followed by Cap Analysis of Gene Expression (CAGE-Seq). Here, we describe the quality control steps adopted in our analysis pipeline before determining the knockdown effects of three ASOs per lncRNA target on the LEC or BEC transcriptomes. In this regard, we especially observed that the choice of negative control ASOs can dramatically impact the conclusions drawn from the analysis depending on the cellular background., Conclusion: In conclusion, the comparison of negative control ASO effects on the targeted cell type transcriptomes highlights the essential need to select a proper control set of multiple negative control ASO based on the investigated cell types., (© 2021. The Author(s).)

Published

2021

9. Discovery of widespread transcription initiation at microsatellites predictable by sequence-based deep neural network.

Author

Grapotte M, Saraswat M, Bessière C, Menichelli C, Ramilowski JA, Severin J, Hayashizaki Y, Itoh M, Tagami M, Murata M, Kojima-Ishiyama M, Noma S, Noguchi S, Kasukawa T, Hasegawa A, Suzuki H, Nishiyori-Sueki H, Frith MC, Chatelain C, Carninci P, de Hoon MJL, Wasserman WW, Bréhélin L, and Lecellier CH

Subjects

A549 Cells, Animals, Base Sequence, Computational Biology methods, Deep Learning, Enhancer Elements, Genetic, Genome, Human, High-Throughput Nucleotide Sequencing, Humans, Mice, Neurodegenerative Diseases diagnosis, Neurodegenerative Diseases metabolism, Polymorphism, Genetic, Promoter Regions, Genetic, Microsatellite Repeats, Neural Networks, Computer, Neurodegenerative Diseases genetics, Transcription Initiation Site, Transcription Initiation, Genetic

Abstract

Using the Cap Analysis of Gene Expression (CAGE) technology, the FANTOM5 consortium provided one of the most comprehensive maps of transcription start sites (TSSs) in several species. Strikingly, ~72% of them could not be assigned to a specific gene and initiate at unconventional regions, outside promoters or enhancers. Here, we probe these unassigned TSSs and show that, in all species studied, a significant fraction of CAGE peaks initiate at microsatellites, also called short tandem repeats (STRs). To confirm this transcription, we develop Cap Trap RNA-seq, a technology which combines cap trapping and long read MinION sequencing. We train sequence-based deep learning models able to predict CAGE signal at STRs with high accuracy. These models unveil the importance of STR surrounding sequences not only to distinguish STR classes, but also to predict the level of transcription initiation. Importantly, genetic variants linked to human diseases are preferentially found at STRs with high transcription initiation level, supporting the biological and clinical relevance of transcription initiation at STRs. Together, our results extend the repertoire of non-coding transcription associated with DNA tandem repeats and complexify STR polymorphism.

Published

2021

10. LETR1 is a lymphatic endothelial-specific lncRNA governing cell proliferation and migration through KLF4 and SEMA3C.

Author

Ducoli L, Agrawal S, Sibler E, Kouno T, Tacconi C, Hon CC, Berger SD, Müllhaupt D, He Y, Kim J, D'Addio M, Dieterich LC, Carninci P, de Hoon MJL, Shin JW, and Detmar M

Subjects

Cell Movement, Cell Proliferation, Endothelial Cells metabolism, Gene Expression Regulation, Humans, Kruppel-Like Factor 4, Kruppel-Like Transcription Factors genetics, RNA, Long Noncoding, Semaphorins genetics, Endothelial Cells cytology, Kruppel-Like Transcription Factors metabolism, Semaphorins metabolism

Abstract

Recent studies have revealed the importance of long noncoding RNAs (lncRNAs) as tissue-specific regulators of gene expression. There is ample evidence that distinct types of vasculature undergo tight transcriptional control to preserve their structure, identity, and functions. We determine a comprehensive map of lineage-specific lncRNAs in human dermal lymphatic and blood vascular endothelial cells (LECs and BECs), combining RNA-Seq and CAGE-Seq. Subsequent antisense oligonucleotide-knockdown transcriptomic profiling of two LEC- and two BEC-specific lncRNAs identifies LETR1 as a critical gatekeeper of the global LEC transcriptome. Deep RNA-DNA, RNA-protein interaction studies, and phenotype rescue analyses reveal that LETR1 is a nuclear trans-acting lncRNA modulating, via key epigenetic factors, the expression of essential target genes, including KLF4 and SEMA3C, governing the growth and migratory ability of LECs. Together, our study provides several lines of evidence supporting the intriguing concept that every cell type expresses precise lncRNA signatures to control lineage-specific regulatory programs.

Published

2021

11. Comparative transcriptomics of primary cells in vertebrates.

Author

Alam T, Agrawal S, Severin J, Young RS, Andersson R, Arner E, Hasegawa A, Lizio M, Ramilowski JA, Abugessaisa I, Ishizu Y, Noma S, Tarui H, Taylor MS, Lassmann T, Itoh M, Kasukawa T, Kawaji H, Marchionni L, Sheng G, R R Forrest A, Khachigian LM, Hayashizaki Y, Carninci P, and de Hoon MJL

Subjects

Animals, Chickens genetics, Dogs, Gene Expression Profiling, Gene Regulatory Networks, Humans, Mice, MicroRNAs metabolism, Nucleotide Motifs, Principal Component Analysis, Promoter Regions, Genetic, Rats, Species Specificity, Transcription Factors metabolism, Evolution, Molecular, Transcriptome

Abstract

Gene expression profiles in homologous tissues have been observed to be different between species, which may be due to differences between species in the gene expression program in each cell type, but may also reflect differences in cell type composition of each tissue in different species. Here, we compare expression profiles in matching primary cells in human, mouse, rat, dog, and chicken using Cap Analysis Gene Expression (CAGE) and short RNA (sRNA) sequencing data from FANTOM5. While we find that expression profiles of orthologous genes in different species are highly correlated across cell types, in each cell type many genes were differentially expressed between species. Expression of genes with products involved in transcription, RNA processing, and transcriptional regulation was more likely to be conserved, while expression of genes encoding proteins involved in intercellular communication was more likely to have diverged during evolution. Conservation of expression correlated positively with the evolutionary age of genes, suggesting that divergence in expression levels of genes critical for cell function was restricted during evolution. Motif activity analysis showed that both promoters and enhancers are activated by the same transcription factors in different species. An analysis of expression levels of mature miRNAs and of primary miRNAs identified by CAGE revealed that evolutionary old miRNAs are more likely to have conserved expression patterns than young miRNAs. We conclude that key aspects of the regulatory network are conserved, while differential expression of genes involved in cell-to-cell communication may contribute greatly to phenotypic differences between species., (© 2020 Alam et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

12. Recounting the FANTOM CAGE-Associated Transcriptome.

Author

Imada EL, Sanchez DF, Collado-Torres L, Wilks C, Matam T, Dinalankara W, Stupnikov A, Lobo-Pereira F, Yip CW, Yasuzawa K, Kondo N, Itoh M, Suzuki H, Kasukawa T, Hon CC, de Hoon MJL, Shin JW, Carninci P, Jaffe AE, Leek JT, Favorov A, Franco GR, Langmead B, and Marchionni L

Subjects

Databases, Genetic, Enhancer Elements, Genetic, Gene Expression Profiling, Genome, Human, Humans, Neoplasms genetics, Organ Specificity, Prognosis, RNA, Long Noncoding genetics, RNA, Long Noncoding metabolism, RNA, Messenger metabolism, Transcriptome

Abstract

Long noncoding RNAs (lncRNAs) have emerged as key coordinators of biological and cellular processes. Characterizing lncRNA expression across cells and tissues is key to understanding their role in determining phenotypes, including human diseases. We present here FC-R2, a comprehensive expression atlas across a broadly defined human transcriptome, inclusive of over 109,000 coding and noncoding genes, as described in the FANTOM CAGE-Associated Transcriptome (FANTOM-CAT) study. This atlas greatly extends the gene annotation used in the original recount2 resource. We demonstrate the utility of the FC-R2 atlas by reproducing key findings from published large studies and by generating new results across normal and diseased human samples. In particular, we (a) identify tissue-specific transcription profiles for distinct classes of coding and noncoding genes, (b) perform differential expression analysis across thirteen cancer types, identifying novel noncoding genes potentially involved in tumor pathogenesis and progression, and (c) confirm the prognostic value for several enhancer lncRNAs expression in cancer. Our resource is instrumental for the systematic molecular characterization of lncRNA by the FANTOM6 Consortium. In conclusion, comprised of over 70,000 samples, the FC-R2 atlas will empower other researchers to investigate functions and biological roles of both known coding genes and novel lncRNAs., (© 2020 Imada et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

13. Functional annotation of human long noncoding RNAs via molecular phenotyping.

Author

Ramilowski JA, Yip CW, Agrawal S, Chang JC, Ciani Y, Kulakovskiy IV, Mendez M, Ooi JLC, Ouyang JF, Parkinson N, Petri A, Roos L, Severin J, Yasuzawa K, Abugessaisa I, Akalin A, Antonov IV, Arner E, Bonetti A, Bono H, Borsari B, Brombacher F, Cameron CJ, Cannistraci CV, Cardenas R, Cardon M, Chang H, Dostie J, Ducoli L, Favorov A, Fort A, Garrido D, Gil N, Gimenez J, Guler R, Handoko L, Harshbarger J, Hasegawa A, Hasegawa Y, Hashimoto K, Hayatsu N, Heutink P, Hirose T, Imada EL, Itoh M, Kaczkowski B, Kanhere A, Kawabata E, Kawaji H, Kawashima T, Kelly ST, Kojima M, Kondo N, Koseki H, Kouno T, Kratz A, Kurowska-Stolarska M, Kwon ATJ, Leek J, Lennartsson A, Lizio M, López-Redondo F, Luginbühl J, Maeda S, Makeev VJ, Marchionni L, Medvedeva YA, Minoda A, Müller F, Muñoz-Aguirre M, Murata M, Nishiyori H, Nitta KR, Noguchi S, Noro Y, Nurtdinov R, Okazaki Y, Orlando V, Paquette D, Parr CJC, Rackham OJL, Rizzu P, Sánchez Martinez DF, Sandelin A, Sanjana P, Semple CAM, Shibayama Y, Sivaraman DM, Suzuki T, Szumowski SC, Tagami M, Taylor MS, Terao C, Thodberg M, Thongjuea S, Tripathi V, Ulitsky I, Verardo R, Vorontsov IE, Yamamoto C, Young RS, Baillie JK, Forrest ARR, Guigó R, Hoffman MM, Hon CC, Kasukawa T, Kauppinen S, Kere J, Lenhard B, Schneider C, Suzuki H, Yagi K, de Hoon MJL, Shin JW, and Carninci P

Subjects

Cell Growth Processes genetics, Cell Movement genetics, Fibroblasts cytology, Fibroblasts metabolism, Humans, KCNQ Potassium Channels metabolism, Molecular Sequence Annotation, Oligonucleotides, Antisense, RNA, Long Noncoding antagonists & inhibitors, RNA, Long Noncoding metabolism, RNA, Small Interfering, RNA, Long Noncoding physiology

Abstract

Long noncoding RNAs (lncRNAs) constitute the majority of transcripts in the mammalian genomes, and yet, their functions remain largely unknown. As part of the FANTOM6 project, we systematically knocked down the expression of 285 lncRNAs in human dermal fibroblasts and quantified cellular growth, morphological changes, and transcriptomic responses using Capped Analysis of Gene Expression (CAGE). Antisense oligonucleotides targeting the same lncRNAs exhibited global concordance, and the molecular phenotype, measured by CAGE, recapitulated the observed cellular phenotypes while providing additional insights on the affected genes and pathways. Here, we disseminate the largest-to-date lncRNA knockdown data set with molecular phenotyping (over 1000 CAGE deep-sequencing libraries) for further exploration and highlight functional roles for ZNF213-AS1 and lnc-KHDC3L-2 ., (© 2020 Ramilowski et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

14. An integrated expression atlas of miRNAs and their promoters in human and mouse.

Author

de Rie D, Abugessaisa I, Alam T, Arner E, Arner P, Ashoor H, Åström G, Babina M, Bertin N, Burroughs AM, Carlisle AJ, Daub CO, Detmar M, Deviatiiarov R, Fort A, Gebhard C, Goldowitz D, Guhl S, Ha TJ, Harshbarger J, Hasegawa A, Hashimoto K, Herlyn M, Heutink P, Hitchens KJ, Hon CC, Huang E, Ishizu Y, Kai C, Kasukawa T, Klinken P, Lassmann T, Lecellier CH, Lee W, Lizio M, Makeev V, Mathelier A, Medvedeva YA, Mejhert N, Mungall CJ, Noma S, Ohshima M, Okada-Hatakeyama M, Persson H, Rizzu P, Roudnicky F, Sætrom P, Sato H, Severin J, Shin JW, Swoboda RK, Tarui H, Toyoda H, Vitting-Seerup K, Winteringham L, Yamaguchi Y, Yasuzawa K, Yoneda M, Yumoto N, Zabierowski S, Zhang PG, Wells CA, Summers KM, Kawaji H, Sandelin A, Rehli M, Hayashizaki Y, Carninci P, Forrest ARR, and de Hoon MJL

Subjects

Animals, Cells, Cultured, Gene Library, High-Throughput Nucleotide Sequencing, Humans, Mice, MicroRNAs metabolism, Gene Expression Profiling methods, MicroRNAs genetics, Molecular Sequence Annotation, Promoter Regions, Genetic genetics

Abstract

MicroRNAs (miRNAs) are short non-coding RNAs with key roles in cellular regulation. As part of the fifth edition of the Functional Annotation of Mammalian Genome (FANTOM5) project, we created an integrated expression atlas of miRNAs and their promoters by deep-sequencing 492 short RNA (sRNA) libraries, with matching Cap Analysis Gene Expression (CAGE) data, from 396 human and 47 mouse RNA samples. Promoters were identified for 1,357 human and 804 mouse miRNAs and showed strong sequence conservation between species. We also found that primary and mature miRNA expression levels were correlated, allowing us to use the primary miRNA measurements as a proxy for mature miRNA levels in a total of 1,829 human and 1,029 mouse CAGE libraries. We thus provide a broad atlas of miRNA expression and promoters in primary mammalian cells, establishing a foundation for detailed analysis of miRNA expression patterns and transcriptional control regions.

Published

2017