Your search keyword '"Danilenko, Marina"' showing total 14 results

1. Investigating the mechanism of alternative splicing regulation of the RNA-binding proteins T-STAR and Sam68

Author

Danilenko, Marina

Subjects

572.8

Abstract

Alternative splicing is an important mechanism of pre-mRNA processing, regulated by many splicing factors. Some splicing factors as T-STAR, are poorly characterised due to absence of RNA targets identified. The first main aim of this study was to identify the principles for splicing regulation by T-STAR, by characterising its first identified physiological targets Neurexin-2 and Tomosyn-2. The second important aim was to compare the T-STAR and Sam68 splicing regulation on example of Neurexin-2 being a T-STAR specific target, and Tomosyn-2 being regulated by both T-STAR and Sam68. By EMSA analyses, I identified that Neurexin-2 is a direct target of both T-STAR and Sam68. By minigene assays and mutagenesis, I found that T-STAR response element in Neurexin-2 is composite. Individually each AU-rich region is redundant for splicing regulation, but loss of two key groups of AU-rich sequence elements inhibits splicing control by T-STAR. Several splicing regulator proteins have been shown to follow a pattern where binding upstream of a regulated exon leads to splicing repression and binding downstream leads to splicing activation. The T-STAR response element starts just 13 nucleotides downstream of the regulated Neurexin-2 exon, suggesting T-STAR protein binding might physically occlude the 5´splice site. Instead, I found this T-STAR response element can still potently repress splicing even from more distant downstream locations, and surprisingly even when placed upstream of the regulated exon. To find out how general this form of position-independent splicing regulation is I identified AU-rich downstream sequence elements that control splicing patterns of Tomosyn-2 in response to both T-STAR and Sam68. These Tomosyn-2 splicing response sequences similarly repressed splicing when moved upstream of the regulated exon. The T-STAR response element in Neurexin-2 predominantly contained UUAA sequences, while the T-STAR/Sam68 response element in Tomosyn-2 contained UAAA repeats. Conversion of the Neurexin response element to UAAA and UAAAA placed this exon under control of both Sam68 and T-STAR. Current data suggest that T-STAR and Sam68 proteins are unusual in that they repress splicing from either side of the exon. These proteins have subtly different target sequences that can enable them to control distinct patterns of target exons in the cell.

Published

2015

2. Murine Joubert syndrome reveals Hedgehog signaling defects as a potential therapeutic target for nephronophthisis

Author

Hynes, Ann Marie, Giles, Rachel H., Srivastava, Shalabh, Eley, Lorraine, Whitehead, Jennifer, Danilenko, Marina, Raman, Shreya, Slaats, Gisela G., Colville, John G., Ajzenberg, Henry, Kroes, Hester Y., Thelwall, Peter E., Simmons, Nicholas L., Miles, Colin G., and Sayer, John A.

Published

2014

3. The splicing landscape is globally reprogrammed during male meiosis

Author

Schmid, Ralf, Grellscheid, Sushma Nagaraja, Ehrmann, Ingrid, Dalgliesh, Caroline, Danilenko, Marina, Paronetto, Maria Paola, Pedrotti, Simona, Grellscheid, David, Dixon, Richard J., Sette, Claudio, Eperon, Ian C., and Elliott, David J.

Published

2013

4. MBRS-59. SINGLE-CELL WHOLE-GENOME SEQUENCING DISSECTS INTRA-TUMOURAL GENOMIC HETEROGENEITY AND CLONAL EVOLUTION IN CHILDHOOD MEDULLOBLASTOMA

Author

Danilenko, Marina, primary, Zaka, Masood, additional, Keeling, Claire, additional, Crosier, Stephen, additional, Hussain, Rafiqul, additional, Schwalbe, Edward, additional, Williamson, Dan, additional, Coxhead, Jonathan, additional, Rand, Vikki, additional, Bailey, Simon, additional, and Clifford, Steven, additional

Published

2020

5. A SLM2 Feedback Pathway Controls Cortical Network Activity and Mouse Behavior

Author

Ehrmann, Ingrid, Gazzara, Matthew R., Pagliarini, Vittoria, Dalgliesh, Caroline, Kheirollahi-Chadegani, Mahsa, Yaobo Xu, Cesari, Eleonora, Danilenko, Marina, Maclennan, Marie, Lowdon, Kate, Vogel, Tanja, Keskivali-Bond, Piia, Wells, Sara, Cater, Heather, Fort, Philippe, Santibanez-Koref, Mauro, Middei, Silvia, Sette, Claudio, Clowry, Gavin J., Barash, Yoseph, Cunningham, Mark O., Elliott, David J., Institute of Human Genetics (NEWCASTLE UNIVERSITY), Newcastel University, Department of Biomedicine and Prevention, Università degli Studi di Roma Tor Vergata [Roma], Institute of Anatomy and Cell Biology, Albert-Ludwigs-Universität Freiburg, Mary Lyon Centre, MRC Harwell Institute, Medical Research Council Harwell (Mammalian Genetics Unit and Mary Lyon Centre), Medical Research Counc, Centre de recherche en Biologie Cellulaire (CRBM), Université Montpellier 2 - Sciences et Techniques (UM2)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Université Montpellier 1 (UM1), Dulbecco Telethon Institute/Department of Biology, University of Pennsylvania [Philadelphia], United States Nuclear Regulatory Commission (U.S.NRC), Institute of Genetic Medicine [Newcastle, U.K.], and Newcastle University [Newcastle]

Subjects

Genetics and Molecular Biology (all), hippocampus, Knockout, brain, [SDV.CAN]Life Sciences [q-bio]/Cancer, [SDV.BC.BC]Life Sciences [q-bio]/Cellular Biology/Subcellular Processes [q-bio.SC], [SDV.BID.SPT]Life Sciences [q-bio]/Biodiversity/Systematics, Phylogenetics and taxonomy, Biochemistry, Article, Mice, alternative splicing, RNA Precursors, Animals, Homeostasis, Neural Cell Adhesion Molecules, lcsh:QH301-705.5, Adaptor Proteins, Signal Transducing, Settore BIO/16 - ANATOMIA UMANA, Mice, Knockout, Behavior, Behavior, Animal, Animal, Pyramidal Cells, Calcium-Binding Proteins, Signal Transducing, Adaptor Proteins, RNA-Binding Proteins, Neurexin splicing, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, neuron, gene expression, RNA binding proteins, RNA-seq, transcriptome, Alternative Splicing, Synapses, Nerve Net, Biochemistry, Genetics and Molecular Biology (all), [SDV.BDD.EO]Life Sciences [q-bio]/Development Biology/Embryology and Organogenesis, lcsh:Biology (General)

Abstract

Summary The brain is made up of trillions of synaptic connections that together form neural networks needed for normal brain function and behavior. SLM2 is a member of a conserved family of RNA binding proteins, including Sam68 and SLM1, that control splicing of Neurexin1-3 pre-mRNAs. Whether SLM2 affects neural network activity is unknown. Here, we find that SLM2 levels are maintained by a homeostatic feedback control pathway that predates the divergence of SLM2 and Sam68. SLM2 also controls the splicing of Tomosyn2, LysoPLD/ATX, Dgkb, Kif21a, and Cask, each of which are important for synapse function. Cortical neural network activity dependent on synaptic connections between SLM2-expressing-pyramidal neurons and interneurons is decreased in Slm2-null mice. Additionally, these mice are anxious and have a decreased ability to recognize novel objects. Our data reveal a pathway of SLM2 homeostatic auto-regulation controlling brain network activity and behavior., Graphical Abstract, Highlights • SLM2 splicing targets are spatially controlled within the hippocampus • RNA-seq reveals SLM2 feedback control and synaptic protein splicing targets • Loss of SLM2 dampens patterns of hippocampal γ oscillations • Loss of SLM2 changes mouse behavior that depends on these neural networks, SLM2 is an RNA binding protein conserved for ∼550 million years. Ehrmann et al. identify a homeostatic feedback pathway that controls SLM2 expression across the brain. Loss of SLM2 protein causes defects in neural network activity and changes mouse behavior.

Published

2016

6. Transcriptomic profiling of human skin biopsies in the clinical trial setting: A protocol for high quality RNA extraction from skin tumours

Author

Danilenko, Marina, primary, Stones, Robert, additional, and Rajan, Neil, additional

Published

2018

7. Binding site density enables paralog-specific activity of SLM2 and Sam68 proteins in Neurexin2 AS4 splicing control

Author

Danilenko, Marina, Dalgliesh, Caroline, Pagliarini, Vittoria, Naro, Chiara, Ehrmann, Ingrid, Feracci, Mikael, Kheirollahi-Chadegani, Mahsa, Tyson-Capper, Alison, Clowry, Gavin J., Fort, Philippe, Dominguez, Cyril, Sette, Claudio, Elliott, David J., Pagliarini, Vittoria (ORCID:0000-0002-2388-0675), Naro, Chiara (ORCID:0000-0002-3135-3218), Sette, Claudio (ORCID:0000-0003-2864-8266), Danilenko, Marina, Dalgliesh, Caroline, Pagliarini, Vittoria, Naro, Chiara, Ehrmann, Ingrid, Feracci, Mikael, Kheirollahi-Chadegani, Mahsa, Tyson-Capper, Alison, Clowry, Gavin J., Fort, Philippe, Dominguez, Cyril, Sette, Claudio, Elliott, David J., Pagliarini, Vittoria (ORCID:0000-0002-2388-0675), Naro, Chiara (ORCID:0000-0002-3135-3218), and Sette, Claudio (ORCID:0000-0003-2864-8266)

Abstract

SLM2 and Sam68 are splicing regulator paralogs that usually overlap in function, yet only SLM2 and not Sam68 controls the Neurexin2 AS4 exon important for brain function. Herein we find that SLM2 and Sam68 similarly bind to Neurexin2 pre-mRNA, both within the mouse cortex and in vitro. Protein domain-swap experiments identify a region including the STAR domain that differentiates SLM2 and Sam68 activity in splicing target selection, and confirm that this is not established via the variant amino acids involved in RNA contact. However, far fewer SLM2 and Sam68 RNA binding sites flank the Neurexin2 AS4 exon, compared with those flanking the Neurexin1 and Neurexin3 AS4 exons under joint control by both Sam68 and SLM2. Doubling binding site numbers switched paralog sensitivity, by placing the Neurexin2 AS4 exon under joint splicing control by both Sam68 and SLM2. Our data support a model where the density of shared RNA binding sites around a target exon, rather than different paralog-specific protein-RNA binding sites, controls functional target specificity between SLM2 and Sam68 on the Neurexin2 AS4 exon. Similar models might explain differential control by other splicing regulators within families of paralogs with indistinguishable RNA binding sites.

Published

2017

8. Development and validation of LC–MS/MS with in-source collision-induced dissociation for the quantification of pegcantratinib in human skin tumors

Author

Zangarini, Monique, primary, Rajan, Neil, additional, Danilenko, Marina, additional, Berry, Philip, additional, Traversa, Silvio, additional, and Veal, Gareth J, additional

Published

2017

9. Binding site density enables paralog-specific activity of SLM2 and Sam68 proteins in Neurexin2 AS4 splicing control

Author

Danilenko, Marina, primary, Dalgliesh, Caroline, additional, Pagliarini, Vittoria, additional, Naro, Chiara, additional, Ehrmann, Ingrid, additional, Feracci, Mikael, additional, Kheirollahi-Chadegani, Mahsa, additional, Tyson-Capper, Alison, additional, Clowry, Gavin J, additional, Fort, Philippe, additional, Dominguez, Cyril, additional, Sette, Claudio, additional, and Elliott, David J., additional

Published

2016

10. Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons

Author

Best, Andrew, James, Katherine, Dalgliesh, Caroline, Hong, Elaine, Kheirolahi-Kouhestani, Mahsa, Curk, Tomaz, Yaobo Xu, Danilenko, Marina, Hussain, Rafiq, Keavney, Bernard, Wipat, Anil, Klinck, Roscoe, Cowell, Ian G., Cheong Lee, Ka, Austin, Caroline A., Venables, Julian P., Chabot, Benoit, Santibanez Koref, Mauro, Tyson-Capper, Alison, and Elliott, David J.

Subjects

Serine-Arginine Splicing Factors, C100, RNA-Binding Proteins, Nerve Tissue Proteins, C500, Exons, C700, Article, Alternative Splicing, Cell Line, Tumor, Checkpoint Kinase 1, MCF-7 Cells, Humans, RNA, Messenger, Protein Kinases

Abstract

Alternative splicing—the production of multiple messenger RNA isoforms from a single gene—is regulated in part by RNA binding proteins. While the RBPs transformer2 alpha (Tra2α) and Tra2β have both been implicated in the regulation of alternative splicing, their relative contributions to this process are not well understood. Here we find simultaneous—but not individual—depletion of Tra2α and Tra2β induces substantial shifts in splicing of endogenous Tra2β target exons, and that both constitutive and alternative target exons are under dual Tra2α–Tra2β control. Target exons are enriched in genes associated with chromosome biology including CHEK1, which encodes a key DNA damage response protein. Dual Tra2 protein depletion reduces expression of full-length CHK1 protein, results in the accumulation of the DNA damage marker γH2AX and decreased cell viability. We conclude Tra2 proteins jointly control constitutive and alternative splicing patterns via paralog compensation to control pathways essential to the maintenance of cell viability., RNA binding proteins are key regulators of alternative splicing. Here, Best et al. show that the human Tra2α and Tra2ß RNA binding proteins jointly contribute to the control of constitutive and alternative splicing events to regulate essential biological processes including the response to DNA damage.

Published

2014

11. Structural basis of RNA recognition and dimerization by the STAR proteins T-STAR and Sam68

Author

Feracci, Mikael, primary, Foot, Jaelle N., additional, Grellscheid, Sushma N., additional, Danilenko, Marina, additional, Stehle, Ralf, additional, Gonchar, Oksana, additional, Kang, Hyun-Seo, additional, Dalgliesh, Caroline, additional, Meyer, N. Helge, additional, Liu, Yilei, additional, Lahat, Albert, additional, Sattler, Michael, additional, Eperon, Ian C., additional, Elliott, David J., additional, and Dominguez, Cyril, additional

Published

2016

12. Binding site density enables paralog-specific activity of SLM2 and Sam68 proteins in Neurexin2AS4 splicing control.

Author

Danilenko, Marina, Dalgliesh, Caroline, Pagliarini, Vittoria, Naro, Chiara, Ehrmann, Ingrid, Feracci, Mikael, Kheirollahi-Chadegani, Mahsa, Tyson-Capper, Alison, Clowry, Gavin J., Fort, Philippe, Dominguez, Cyril, Sette, Claudio, and Elliott, David J.

Published

2017

13. The Tissue-Specific RNA Binding Protein T-STAR Controls Regional Splicing Patterns of Neurexin Pre-mRNAs in the Brain

Author

Ehrmann, Ingrid, primary, Dalgliesh, Caroline, additional, Liu, Yilei, additional, Danilenko, Marina, additional, Crosier, Moira, additional, Overman, Lynn, additional, Arthur, Helen M., additional, Lindsay, Susan, additional, Clowry, Gavin J., additional, Venables, Julian P., additional, Fort, Philippe, additional, and Elliott, David J., additional

Published

2013

14. Binding site density enables paralog-specific activity of SLM2 and Sam68 proteins in Neurexin2 AS4 splicing control.

Author

Danilenko M, Dalgliesh C, Pagliarini V, Naro C, Ehrmann I, Feracci M, Kheirollahi-Chadegani M, Tyson-Capper A, Clowry GJ, Fort P, Dominguez C, Sette C, and Elliott DJ

Subjects

Adaptor Proteins, Signal Transducing genetics, Alternative Splicing, Animals, Binding Sites, Exons, Introns, Mice, Mice, Knockout, Nerve Tissue Proteins metabolism, Protein Domains, RNA Precursors metabolism, RNA, Messenger metabolism, RNA-Binding Proteins chemistry, RNA-Binding Proteins genetics, Substrate Specificity, Adaptor Proteins, Signal Transducing metabolism, Nerve Tissue Proteins genetics, RNA-Binding Proteins metabolism

Abstract

SLM2 and Sam68 are splicing regulator paralogs that usually overlap in function, yet only SLM2 and not Sam68 controls the Neurexin2 AS4 exon important for brain function. Herein we find that SLM2 and Sam68 similarly bind to Neurexin2 pre-mRNA, both within the mouse cortex and in vitro. Protein domain-swap experiments identify a region including the STAR domain that differentiates SLM2 and Sam68 activity in splicing target selection, and confirm that this is not established via the variant amino acids involved in RNA contact. However, far fewer SLM2 and Sam68 RNA binding sites flank the Neurexin2 AS4 exon, compared with those flanking the Neurexin1 and Neurexin3 AS4 exons under joint control by both Sam68 and SLM2. Doubling binding site numbers switched paralog sensitivity, by placing the Neurexin2 AS4 exon under joint splicing control by both Sam68 and SLM2. Our data support a model where the density of shared RNA binding sites around a target exon, rather than different paralog-specific protein-RNA binding sites, controls functional target specificity between SLM2 and Sam68 on the Neurexin2 AS4 exon. Similar models might explain differential control by other splicing regulators within families of paralogs with indistinguishable RNA binding sites., (© The Author(s) 2016. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2017